• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    The present invention relates to an induction heating system (200) using a ferromagnetic susceptor (110) mounted near the outside of a flight surface of an aircraft. At least one electrically conductive coil (120) is mounted near the ferromagnetic susceptor (110). The at least one electrically conductive coil (120) is powered by a first source (161a) at a first frequency. At least one compensation coil (160) is mounted near the ferromagnetic susceptor (110), having a geometry determined to provide substantially zero net flux with respect to the at least one electrically conductive coil (120) and positioned to induce a induction heating where the first plurality of electrically conductive coils lack induction induced heating coverage. The at least one compensation coil (160) is powered by a second AC source (161b) at a second frequency.
    公开号:FR3027872A1
    申请号:FR1560309
    申请日:2015-10-28
    公开日:2016-05-06
    发明作者:John R Hull;Vyacheslav Khozikov;Robert J Miller;Stephen R Amorosi;Rangasamy Elangovan
    申请人:Boeing Co;
    IPC主号:
    专利说明:

    [0001] INDIVIDUALLY HEATED INDUCTION HEATING COILS Embodiments of the invention generally relate to systems for preventing frost formation on aircraft and, more particularly, embodiments for coil geometries for a conventional heating system. induction using a pair of coils connected to a first power system and a third coil connected to a second power system that produces uniform heating in a susceptor sheet ("susceptor sheet"). The geometry of the coils is determined to provide zero flux coupling between the pair of coils and the third coil resulting in minimum coupling between the two power systems.
    [0002] In this document, a coil is constituted by a set of turns which can be reduced to a single turn. An induction-heated anti-ice system for use in an aircraft generally incorporates a ferromagnetic susceptor, one or more heating coils, and a power supply for providing an alternating current to the coils. For the heating of a wing leading edge, the susceptor is either integrated in the erosion protection of the wing, or is placed immediately behind the erosion protection and in good thermal contact with it. The heating coils are placed immediately behind the susceptor. When an alternating current flows in the coils, the magnetic field produced by the coils is inductively coupled in the ferromagnetic susceptor. With a magnetic flux that varies in the susceptor, electric currents are induced in the susceptor and, because the susceptor has electrical resistivity, Joule heating results in the susceptor. When the thermal power per unit area of the Joule heating inside the susceptor is greater than the heat transfer from the susceptor to the surrounding medium, the temperature of the susceptor increases. The concept of induction heating has several advantages in anti-icing systems. From the electrical point of view, it is very efficient and the heat is deposited immediately in the components of the vehicle on which it is desired to avoid the formation of frost. It also offers a system that is easy to install and requires little or no fasteners.
    [0003] Design constraints for induction heating systems on vehicles favor the use of flat coils, such as spiral slabs. The coil will generally follow the contour of the susceptor, which in turn is patterned to follow the profile of the surface on which frost protection is desired, such as a leading edge of the wing or the forward fairing of the nacelle. engine. The geometry of the spiral slab will always result in an area in which the tangential component of the magnetic field is a minimum. This minimum of the field occurs because the current flow in the filaments on both sides of this area is in opposite directions and the magnetic field produced by these current flows vanishes at the center of the coil. In a circular spiral slab, the minimum of the field is at the inner origin of the spiral. For an elongated ellipsoidal spiral, the minimum of the field occurs along a line segment in the middle of the coil. The area on the susceptor that is adjacent to the minimum of the field on the coil will be heated much less than the rest of the susceptor. The normal component of the incident magnetic field produces minimal heating in the susceptor. In addition, the heat transfer on the vehicle is such that it is mainly transverse to the thickness of the susceptor. In addition, the thickness of the susceptor is low. Thus, there is negligible heat transfer within the susceptor from the susceptor portions where the magnetic field is substantial toward the susceptor portion where the magnetic field is at a minimum. Because of these physical functional conditions, there will always be a relative cold spot on the susceptor. The current throughout the coil must be sufficient to maintain this point above a temperature at which frost will form. This current is much higher than that required to maintain other parts of the susceptor above the frost formation temperature, and thus induction heating will be less effective than would be if all the susceptor parts were heated just enough to keep it above the frosting temperature. In addition, portions of the susceptor that have the greatest amount of heating have the potential to reach a temperature high enough to thermally damage the structure of the vehicle that is near the susceptor. It is therefore desirable to provide a structural induction heating system that eliminates geometry-induced cold spots to allow for more uniform heating of the susceptor in a frost protection system. The application for which the present application claims priority is co-pendent with US Patent Application No. 14/195491 filed 03/03/2014 with the title SYSTEMS AND METHODS FOR PREDICTING AND CONTROLLING ICE FORMATION (systems and methods for detecting ice formation as well as to perform the deicing) having a common assignee with the present application. Exemplary embodiments provide an induction heating system comprising a ferromagnetic susceptor mounted near the outside of a flight surface of an aircraft. At least one electrically conductive coil is mounted near the ferromagnetic susceptor. The at least one electrically conductive coil is powered by a first power source at a first frequency. At least one compensation coil is mounted near the ferromagnetic susceptor, having a geometry determined to substantially provide zero net flux with respect to the at least one electrically conductive coil and positioned to induce induction heating where the first plurality of Electrically conductive coils lack of inductive induction heating cover. The at least one compensation coil is powered by a second AC source at a second frequency.
    [0004] A method for providing uniform induction heating for deicing and anti-icing of flight surfaces on an aircraft is provided by the described embodiments, wherein a ferromagnetic susceptor is provided near the outside of a surface of the aircraft. flight of an aircraft. A first plurality of electrically conductive coils is mounted near the ferromagnetic susceptor to inductively heat the ferromagnetic susceptor. At least one compensation coil is mounted near the ferromagnetic susceptor, having a geometry determined to substantially provide zero net flux with respect to the at least one electrically conductive coil and positioned to induce induction heating where the first plurality of electrically conductive coils lack of inductive induced heating coverage. The features, functions and advantages that have been addressed can be achieved independently in various embodiments of the present description or can be combined in still other embodiments, of which other details can be observed with reference to the description herein. below and drawings. Figure 1A is a sectional side view of a susceptor and induction heater coils on a leading edge; Figure 1B is a partial sectional view in the span direction along the lines FIG. 1B-FIG. 1B in Figure lA; Figure 1C is a rear view of the induction heating system of Figure 1A; Figure 2A is a schematic view of a pair of induction heating coils with a compensation coil for uniform heating and associated power sources; Figure 2B is a sectional view of the pair of induction heating coils and the compensation coil of Figure 2A; Figure 2C is a schematic view of the induction heating coils with a compensation coil for uniform heating and an alternative arrangement of power sources; Figure 3 is a schematic view of a pair of induction heating coils with a pair of compensation coils for uniform heating; Figure 4A is a perspective rear view of an induction heating system using solenoid coils for a nacelle leading edge; Figure 4B is a partial detail view of the solenoid coil induction heating system of Figure 4A; Figure 5 is a partial detail view of the solenoid coils with an associated compensation coil; and Figure 6 is a flowchart of a method for uniform induction heating for deicing and anti-icing of flight surfaces on an aircraft embodying the described embodiments. The embodiments described herein provide a coil geometry that provides uniform heating over the entire susceptor. Illustrative embodiments use a pair of coils, wired in series to provide maximum heating along the leading edge line of the leading edge. Induction heating of the susceptor by each coil has a cold point in a location remote from the leading edge. A compensation coil is superimposed over the pair of coils with a relative geometry defined for zero flux coupling with the pair of coils and providing heat to the susceptor at the cold points of the coil pair. The compensation coil is powered by a power supply independent of the power supply that powers the pair of coils. The geometry of the compensation coil is predetermined to provide that a net magnetic flux from the pair of coils which makes a connection to the compensation coil is essentially zero. This geometry is a net zero flux coupling and the mutual inductance between the pair of coils and the compensation coil is negligible. By symmetry, the total voltage induced on the pair of coils by the magnetic flux emanating from the compensation coil is essentially zero. In this way, the two independent power supplies do not interfere with each other. Toroidal wound spiral wafers or segmented solenoids, such as those that may exist in anti-icing systems for the front shroud of an engine nacelle, may be used for the coils.
    [0005] Referring to the drawings, a lateral cross-section of a susceptor and a pair of heating coils is shown in Figure 1A in a typical configuration for anti-icing application for a wing leading edge. The direction of movement of the vehicle would generally be to the left in Figure 1A. An induction heating system 100 includes a susceptor 110 and a pair of heating coils 120. The susceptor 110 may be a metal foil or a metal alloy. A leading edge leading edge line is indicated by reference 105. The susceptor 110 follows the profile of the leading edge of the wing. A sectional view as represented by lines FIG. 1B-FIG.1B in Figure 1A of an upper segment of the system 100 is shown in Figure 1B, demonstrating that the profile extends in the page, as it would along a portion of the length of the wing. As is more visible in a rear view of the pair of heating coils 120 along lines FIG. 1CFIG.1C in Figure 1A, the pair of coils 120 comprises an upper coil 130 and a lower coil 140. The upper coil 130 has a current lead 135; and the lower coil 140 has a current lead 145. The arrows show the relative direction of the current flow at a given instant. The upper and lower coils are electrically connected by a conductor 150 so that both coils have a current in the same direction along the front tip line 105. Induction heating of the susceptor by the upper coil 130 will result in a cold spot 132 and induction heating of the susceptor by the lower coil 140 will result in a cold point 142. For the elongated coil of the coils 130 and 140, the field minimum occurs along a line segment in the middle of the coil. This minimum of field occurs because the current flow in the filaments on either side of this area is in opposite directions and the magnetic field produced by these currents vanishes at the center of the coil. For the embodiment shown, the pair of coils take the form of an elongated pair of flat coiled coils with square corners. The number of windings in the figure is low for better viewing. The spiral profile and the number of windings may vary in actual embodiments as necessary to provide the desired induction heating of the susceptor. The basic configuration of an exemplary embodiment of induction heating coils with uniform heating is shown in FIGS. 2A and 2B. The induction heating system 200 incorporates the elements of the induction heating system 100 illustrated in FIGS. 1A-1C, with the addition of a compensation coil, a third coil 160, having current leads 162 and 164. The third coil 160 is mounted on the top (inside) of the pair of coils 120 for the embodiment shown, and the third coil 160 is symmetrical with respect to the front tip line 105, as is also the pair of coils 120. The third coil 160 is placed on the pair of coils 120 with a geometric relationship in which the net magnetic flux coupling of the pair of coils 120 to the third coil 160 is substantially zero; a coupling condition with zero flux or net zero flow. The third coil 160 is shown with a single turn with square corners in Fig. 2A, mounted with a portion of the coil aligned on the line segment in the middle of each coil of the coil pair 120 where the minimum of the field occurs. where the flow of current in the filaments on each side is in opposite directions. In alternate embodiments, the third coil 160 may have an arbitrary number of turns with different geometric shapes positioned to provide the net null flow condition with respect to the coil pair 120. Similarly, the number of turns in the upper and lower coils 130 and 140 may be smaller or larger than that shown in Figure 2A. In Fig. 2A, the upper and lower coils 130 and 140 are shown to be symmetrical with respect to the leading edge line 105. However, this is generally not a constraint, especially since the top of an edge wing attack usually has a different geometry than the lower part.
    [0006] Even with an asymmetric pair, a spacing between coil filaments and the geometrical pattern of the third coil 160 can be adjusted so that the nil flux coupling condition is maintained. For the exemplary embodiment of Figures 2A and 2B, the pair of coils 120 and the third coil 160 have independent power supplies 161a and 161b and the frequency of the two power supplies is different. In actual embodiments, the difference in frequency can be very small. If the three coils were fed at the same frequency with a constant phase difference, the cold spots of the coil pair would not be eliminated but simply moved to a different position. The operation of the third coil 160 at a different frequency from the pair of coils 120 ensures that the average heating of the third coil is added to the average heating of the pair of coils. In another embodiment shown in FIG. 2C, the pair of coils 120 and the third coil 160 are connected to the same power supply 161, with the pair of coils 120 in parallel with the third coil 160. However, the third coil 160 has a phase adjusting component 163 which can use a solenoid, a capacitor or a combination thereof, in the form of an electronic circuit in series with the third coil and connected to the first DC power supply. 161 which provides a current phase variation for the third coil in a random manner over time. While the presence of the third coil 160 provides most of the improvement in heating uniformity, compared to a pair of coils only, the heating uniformity can be further improved by adjusting the spacing of the coils. filaments in both the horizontal and vertical directions in Figures 2A and 2C. Control of the current ratio in the pair of coils 120 with respect to the third coil 160 by a microprocessor control device 165 or a similar control device associated with at least one of the power supplies can also be used to influence the uniformity of heating. In an actual anti-icing application, absolute uniformity may not be desirable. For example, the maximum heat transfer to the ambient is generally along the leading edge leading edge line and decreases away from the leading edge line. The actual distribution of heat transfer will generally depend on the relative speed of the vehicle and the angle of attack to the airflow. Using the current control described above, susceptor heating can be adjusted to match the expected rate of heat transfer to the ambient environment. Null flux coupling with the coil pair 120 can also be achieved with multiple coils and multiple coil layers. For example, the compensation coil, the third coil 160 in Figure 2A, could instead be a second pair of coils 170, including a left coil 180 and a right coil 190, as shown in Figure 3. A third layer of coils, powered by a third independent power supply could also be added on top of the second layer of coils formed by the second pair of coils 170. Instead of a pair of coils, three or more coils could compose a coil layer . Although described for embodiments having a pair of coils for substantially symmetrical heating of a surface such as a wing leading edge, a single coil for induction heating will have a similar cold spot and a coil. Compensation with a net zero flow geometry with respect to the single coil can be used to provide uniform heating of the cold spot. In addition to the spiral flat coil geometry, the zero flux geometries for improving uniform heating can be implemented in one embodiment using toroidally wound segmented solenoid coil windings such as those that could be used. to provide anti-icing to the front fairing of an engine nacelle. The basic induction induction heater 300 for front fairing anti-icing using such solenoid coils is shown in Figure 4A. As shown in detail in Figure 4B, the coils comprise a set of segmented solenoids 310, toroidally wound and placed within the front fairing 320. In Figures 4A and 4B, the coil wire diameter has been exaggerated. for better viewing. The solenoids 310 could be wired together in series, in parallel or a combination of series and parallel. The front fairing 320 is shown thicker than would be required for erosion protection because hollow passages are often used in the front fairing to reduce noise. The susceptor 330, which is also an erosion protection in the embodiment shown, covers the front fairing 320. The direction of the magnetic flux inside the solenoids is indicated by the arrows 340. As can be seen in FIG. 4, the solenoid bias alternates around the circle of coil segments. This configuration effectively heats the susceptor 330, however, it produces cold spots 350 on the susceptor where the tangential magnetic flux from adjacent solenoids vanishes. An additional coil providing a net zero flux geometry with respect to the solenoids is used as a compensation coil to eliminate cold spots in this type of configuration and shown in Figure 5. In Figure 5, the front fairing is not represented for better viewing. In addition to the segmented solenoids 310, a meander coil 420, acting as the compensation coil, is placed in an induction heating system 400. The meander coil 420 provides an intermediate coil loop to each adjacent pair of solenoids 310 and provides a tangential magnetic flux at the cold points of the segmented solenoids 310. Similar to the case with the spiral flat coils, the meander coil 420 is fed from a different power supply than the segmented solenoids 410. in addition, the net magnetic flux from the solenoids threaded through the meander coil is essentially zero, so that there is no interference between the two independent power supplies.
    [0007] As shown in Figure 6, the described embodiments provide a method for uniform induction heating for deicing and anti-icing of flight surfaces on an aircraft. A ferromagnetic susceptor sheet is provided on the outside of a flight surface of an aircraft, step 602. A first plurality of electrically conductive coils is mounted near the ferromagnetic susceptor sheet to inductively heat the susceptor sheet. The first plurality of electrically conductive coils is powered by a first AC source at a first frequency. A compensation coil having at least one coil or a second plurality of electrically conductive coils is mounted near the ferromagnetic susceptor sheet, having a geometry determined to substantially provide zero net flux with respect to the first plurality of electrically conductive coils and positioned to induce induction heating where the first plurality of electrically conductive coils lack induction induced heating coverage, step 606. The second plurality of electrically conductive coils is powered by a second AC source at a second frequency. For selected embodiments, the first plurality of electrically conductive coils and the compensation coil or the second plurality of electrically conductive coils are positioned such that a predetermined non-uniform induced heat intensity pattern is provided on the electrically conductive coil. susceptor, step 608, to adapt to a variation of a heat transfer rate pattern of the susceptor sheet to an adjacent ambient medium resulting from a pattern of airflow induced by the shape geometry on the flight surfaces. In addition, control of the ratio of currents in the first plurality of electrically conductive coils to the second plurality of electrically conductive coils by a microprocessor control device or similar control device associated with at least one of the power supplies may affect the Heating uniformity, step 610. In addition, the description includes embodiments according to the following clauses: Clause 1. An induction heating system comprising: a ferromagnetic susceptor mounted near the outside of a flight surface an aircraft; at least one electrically conductive coil mounted near the ferromagnetic susceptor, said at least one electrically conductive coil being fed by a first AC source at a first frequency; and at least one compensation coil mounted near the ferromagnetic susceptor, having a geometry determined to provide substantially zero net flux with respect to the at least one electrically conductive coil and positioned to induce induction heating where the at least one an electrically conductive coil lacks induction induced heating cover, said at least one compensation coil being powered by a second AC source at a second frequency. Clause 2. The induction heating system as defined in clause 1, wherein the at least one electrically conductive coil comprises a first plurality of electrically conductive coils. Clause 3. The induction heating system as defined in clause 2, wherein the at least one compensation coil comprises a second plurality of electrically conductive coils.
    [0008] Clause 4. The induction heating system as defined in clause 2 or 3, wherein the first plurality of electrically conductive coils comprises a pair of spiral flat coils. Clause 5. The induction heating system as defined in Clause 4, wherein the pair of flat coil coils is symmetrical with respect to a front tip line and the at least one compensation coil comprises a third coil which is mounted on top of the pair of spiral flat coils, symmetrical with respect to the front tip line. Clause 6. The induction heating system as defined in clauses 2, 3, 4 or 5, wherein the at least one compensation coil comprises a second plurality of electrically conductive coils. Clause 7. The induction heating system as defined in clause 6, wherein the first plurality of electrically conductive coils comprises a pair of spiral flat coils. Clause 8. The induction heating system as defined in Clause 7, wherein the pair of spiral flat coils is symmetrical with respect to a front tip line and the second plurality of electrically conductive coils comprises a second pair of coils. mounted on top of the pair of spiral flat coils symmetrical with respect to the front tip line. Clause 9. The induction heating system as defined in clauses 1, 2, 3, 4, 5, 6, 7 or 8, wherein the second AC source comprises a phase control component in series with the at least one compensation coil and connected to the first AC source, which varies the current phase of a third coil randomly over time.
    [0009] Clause 10. The induction heating system as defined in clause 9, wherein the phase adjusting component is selected from a group comprising a solenoid, a capacitor or a combination thereof. Clause 11. The induction heating system as defined in clauses 2, 3, 4, 5, 6, 7, 8, 9 or 10, wherein the first plurality of electrically conductive coils comprises a plurality of segmented solenoids. Clause 12. The induction heating system as defined in clause 11, wherein the at least one compensation coil comprises a meander coil mounted to provide an intermediate coil loop to each adjacent pair of solenoids. Clause 13. A method for providing uniform induction heating for deicing and anti-icing of flight surfaces on an aircraft, comprising: providing a ferromagnetic susceptor sheet near the outside of flight surfaces of aircraft an aircraft; mounting a first plurality of electrically conductive coils proximate the ferromagnetic susceptor to inductively heat the ferromagnetic susceptor, said first plurality of electrically conductive coils being energized by a first AC source at a first frequency, and mounting at least one compensation coil in the vicinity of the ferromagnetic susceptor, having a geometry determined to substantially provide a zero net flux with respect to the at least one electrically conductive coil and positioned to induce induction heating where the first plurality of electrically coils conductive lack of inductive induction heating cover, said compensation coil being powered by a second AC source at a second frequency. Clause 14. The method as defined in clause 13, wherein the at least one compensation coil comprises a second plurality of electrically conductive coils.
    [0010] Clause 15. The method as defined in clauses 13 or 14, wherein the flight surfaces of the aircraft comprise a leading edge of the wing or a motor fairing. Clause 16. The method as defined in clauses 13, 14 or 15, wherein the second AC source comprises an electronic circuit in series with the at least one compensation coil, said electronic circuit comprising a solenoid, a capacitor or a combination thereof, connected to the first AC source and providing a current phase variation in the second plurality of electrically conductive coils relative to the current phase in the first plurality of electrically conductive coils. Clause 17. The method as defined in clauses 14, 15 or 16, wherein the first and second pluralities of electrically conductive coils are positioned such that a predetermined non-uniform induced heat intensity pattern is made on the sheet of susceptor to accommodate a variation of a heat transfer rate pattern of the susceptor sheet to an adjacent ambient medium resulting from an airflow pattern induced by the shape geometry on the flight surfaces .
    [0011] Clause 18. The method as defined in clauses 14, 15, 16 or 17, further comprising controlling a ratio of currents in the first plurality of electrically conductive coils to the second plurality of electrically conductive coils to affect the uniformity of heating. Clause 19. The method as defined in clause 18, wherein the current ratio control step is performed with a microprocessor controller associated with at least one of the power sources. Since various embodiments of the invention have now been described in detail as required by the patent regulations, those skilled in the art will recognize modifications and substitutions to the specific embodiments described herein. Such modifications fall within the scope and purpose of the present invention as defined in the appended claims.
    权利要求:
    Claims (15)
    [0001]
    REVENDICATIONS1. An induction heating system (200), comprising: a ferromagnetic susceptor (110) mounted proximate the exterior of a flight surface of an aircraft; at least one electrically conductive coil (120) mounted near the ferromagnetic susceptor (110), said at least one electrically conductive coil being energized by a first AC source (161a) at a first frequency; and at least one compensation coil (160) mounted near the ferromagnetic susceptor (110), having a geometry determined to substantially provide a net zero flux with respect to the at least one electrically conductive coil (120) and positioned to induce a induction heating where the at least one electrically conductive coil (120) lacks induced induction heating coverage, said at least one compensation coil (160) being fed by a second AC power source (161b) to a second frequency.
    [0002]
    An induction heating system (200) according to claim 1, wherein the at least one electrically conductive coil (120) comprises a first plurality of electrically conductive coils.
    [0003]
    An induction heating system (200) according to claim 2, wherein the at least one compensation coil (160) comprises a second plurality of electrically conductive coils.
    [0004]
    The induction heating system (200) according to one of claims 2 or 3, wherein the first plurality of electrically conductive coils comprises a pair of spiral flat coils.
    [0005]
    An induction heating system (200) according to claim 4, wherein the pair of spiral flat coils (120) is symmetrical with respect to a leading nose line (105) and the at least one compensation coil (160) comprises a third coil which is mounted on top of the pair of spiral flat coils (120) symmetrical with respect to the leading nose line (105).
    [0006]
    An induction heating system (200) according to one of claims 3, 4 or 5, wherein the first plurality of electrically conductive coils comprises a pair of spiral flat coils.
    [0007]
    An induction heating system (200) according to claim 6, wherein the pair of spiral flat coils is symmetrical with respect to a front tip line (105) and the second plurality of electrically conductive coils comprises a second pair of coils. coils (170) mounted on top of the pair of spiral flat coils symmetrical with respect to the leading edge line (105).
    [0008]
    An induction heating system (200) according to one of claims 1 to 7, wherein the second AC source (161b) comprises a phase adjusting component (163) in series with the at least one coil compensation circuit and connected to the first AC source (161a), which varies the current phase of a third coil (160) randomly over time.
    [0009]
    The induction heating system (200) according to one of claims 2 to 8, wherein the first plurality of electrically conductive coils comprises a plurality of segmented solenoids (310).
    [0010]
    An induction heating system (200) according to claim 9, wherein the at least one compensation coil comprises a meander coil (420) mounted to provide an intermediate coil loop to each adjacent pair of solenoids (310). ).
    [0011]
    A method for providing uniform induction heating for deicing and anti-icing of flight surfaces on an aircraft, comprising: providing a ferromagnetic susceptor sheet proximate the exterior of flight surfaces of an aircraft; aircraft (602); mounting a first plurality of electrically conductive coils proximate the ferromagnetic susceptor (110) to inductively heat the ferromagnetic susceptor (110), said first plurality of electrically conductive coils being energized by a first AC source (161a) at a first frequency; and mounting at least one compensation coil (160) in the vicinity of the ferromagnetic susceptor (110), having a geometry determined to substantially provide zero net flux with respect to the at least one electrically conductive coil (120) and positioned for inducing induction heating where the first plurality of electrically conductive coils lacks inductive induction heating coverage, said one compensating coil being fed by a second AC source (16 lb) at a second frequency.
    [0012]
    The method of claim 11, wherein the at least one compensation coil comprises a second plurality of electrically conductive coils.
    [0013]
    The method of claim 11 or 12, wherein the second AC power source (161b) comprises an electronic circuit in series with the at least one compensation coil (160), said electronic circuit comprising a solenoid, a capacitor or a combination thereof, connected to the first AC source (161a) and providing a current phase variation in the second plurality of electrically conductive coils relative to the current phase in the first plurality of electrically conductive coils.
    [0014]
    The method of claims 12 or 13, wherein the first and second plurality of electrically conductive coils are positioned such that a predetermined non-uniform induced heat intensity pattern is made on the susceptor sheet to accommodate a variation of a heat transfer rate pattern from the susceptor sheet to an adjacent ambient medium resulting from an airflow pattern induced by the shape geometry on the flight surfaces.
    [0015]
    The method of claims 12, 13 or 14, further comprising controlling a ratio of currents in the first plurality of electrically conductive coils to the second plurality of electrically conductive coils to affect heating uniformity.
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    优先权:
    申请号 | 申请日 | 专利标题
    US14526972|2014-10-29|
    US14/526,972|US10399684B2|2014-10-29|2014-10-29|Induction heating coils with uniform heating|
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