The present invention relates to double-sided flat inductor assemblies for simultaneous induction heating of two separate workpieces positioned on opposing sides of the inductor assembly.
It is advantageous in some manufacturing processes to simultaneously heat by electric induction two separate workpieces that, for example, may be different from each other and are joined together after heating.
One example of such manufacturing processes is disclosed in U.S. Pat. No. 6,825,450 B2 (Ribeiro et al.) where the two separate workpieces are an upper crown part of a piston and the second part is the lower crown part of a piston that complements the upper part and when joined together form the piston. The upper crown part may also be called the crown and the lower crown part may also be called the skirt. The complementary sides of the upper and lower crown parts are first heated, for example, by electric induction, and then joined together, for example, by simultaneously pushing and twisting the complementary sides of the upper and lower crown parts together. U.S. Pat. No. 6,637,642 B1 (Lingnau) describes one such joining process. It is advantageous to heat the upper and lower crown parts simultaneously to provide similar heating profiles in both the upper and lower crown parts for the subsequent welding process that joins the upper and lower crown parts together.
It is one object of the present invention to provide a double-sided flat inductor assembly for simultaneous induction heating of two separate workpieces in a manufacturing process.
It is another object of the present invention to provide a double-sided flat inductor assembly for simultaneous induction heating of complementary sides, or faces of two separate workpieces in a manufacturing process and rapid withdrawal of the inductor assembly away from complementary sides of the two separate workpieces to facilitate joining of the heated complementary sides.
In one aspect the present invention is a double-sided flat inductor assembly for simultaneous induction heating of two separate workpieces when the double-sided flat inductor assembly is positioned between two separate workpieces.
In another aspect the present invention is a double-sided flat inductor assembly for simultaneous induction heating of two separate workpieces when the double-sided flat inductor assembly is positioned between two separate workpieces and an apparatus and method of inserting and extracting the double-sided flat inductor assembly between the two separate workpieces.
In another aspect of the present invention is a high speed inductor extraction apparatus and method for positioning an inductor between a workpiece induction heating position and a workpiece non-interference position.
The above and other aspects of the invention are set forth in this specification and the appended claims.
The appended drawings, as briefly summarized below, are provided for exemplary understanding of the invention, and do not limit the invention as further set forth herein.
a) is a side elevational view of a first workpiece side of one example of a double-sided flat inductor assembly of the present invention.
b) is a cross sectional view of the doubled-sided flat inductor assembly through line 1-1 in
a) is a side elevational view of a second workpiece side of one example of a double-sided flat inductor assembly of the present invention.
b) is a cross sectional view of the doubled-sided flat inductor assembly through line 3-3 in
a) and
c) and
a) is a front elevational view of one example of a double-sided inductor extraction assembly of the present invention for a double-sided flat inductor assembly.
b) is a rear elevational view of the double-sided inductor extraction assembly shown in
c) is a side view of the double-sided inductor extraction assembly shown in
d) is a front perspective view of the double-sided inductor extraction assembly shown in
a) is a front elevational view of one example of a double-sided flat inductor assembly of the present invention attached to the double-sided inductor extraction assembly shown in
b) is a front perspective view of the double-sided flat inductor assembly attached to the inductor extraction assembly shown in
c) is a side elevational view of the double-sided flat inductor assembly attached to the inductor extraction assembly shown in
d) is a front perspective view of the double-sided flat inductor assembly of the present invention attached to the inductor extraction assembly shown in
e) is a side elevational view of the double-sided flat inductor assembly attached to the inductor extraction assembly shown in
a) is a front perspective view of a double-sided flat inductor assembly attached to one example of an inductor extraction assembly with the inductor and extraction assemblies in an induction post-heat extracted position.
b) is a side elevational view of the double-sided flat inductor assembly attached to the double-sided inductor extraction assembly shown in
c) is a rear perspective view of the double-sided flat inductor assembly attached to the double-sided inductor extraction assembly shown in
d) is a side elevational view of the double-sided flat inductor assembly attached to the double-sided inductor extraction assembly shown in
a) through
As shown in one embodiment of the invention, first workpiece inductor 12 comprises a first inductor terminal section 12a (also referred to as skirt inductor foot 12a), first inductor riser section 12b (also referred to as skirt inductor leg 12b) and first inductor coil section 12c (also referred to as skirt coil 12c).
As shown in one embodiment of the invention, second workpiece inductor 14 comprises a second inductor terminal section 14a (also referred to as crown inductor foot 14a), second inductor riser section 14b (also referred to as crown inductor leg 14b) and second inductor coil section 14c (also referred to as crown coil 14c).
The first inductor riser section and the second inductor riser section are optional in other embodiments and are a means for electrically interconnecting the first inductor coil section to the first inductor terminal section, and the second inductor coil section to the second inductor terminal section, respectively, if there is a requirement to physically separate the inductor coil sections from the inductor terminal sections.
In this embodiment of the invention first and second inductor coil sections 12c and 14c are each shaped as a spirally-coiled induction coil (or inductor) that is sometimes referred to as a “pancake” coil. The spacing between turns of the spirally-coiled inductor may vary based upon the workpiece geometry being heat treated. For example symmetric spacing between all turns of the coil can result in an electromagnetic ring effect where stronger magnetic fields occur on the inner radial region of the workpiece face being heat treated compared with the outer radial regions. To compensate in some embodiments of the invention the outer turns may be more closely spaced together than the inner turns. For example in
Generally the first inductor coil section and the second inductor coil section, as disclosed herein, can be referred to as planarly oriented coil section with the two planarly oriented coil sections being planarly disposed opposing each other. Deviations from planar, for example, the profiling described herein are within the terminology of a planarly oriented coil section. While the embodiment of the inductor coil sections shown in the drawings is circular other configurations can be used in other embodiments of the invention. In other embodiments the entire first workpiece inductor and the entire second workpiece inductor can be referred to as planarly oriented inductors with the two planarly oriented inductors being planarly disposed opposing each other.
First and second workpiece inductors are suitably joined together electrically, for example, by brazing to form a series electrical circuit between the first and second inductor terminal sections 12a and 14a. First workpiece inductor 12 and second workpiece inductor 14 are connected electrically in series as diagrammatically shown in
As shown in
In this embodiment of the invention the inner coil terminus 12c′ of skirt coil 12c is electrically connected to the inner coil terminus 14c′ of crown coil 14c as shown in
Suitable middle electrical insulating material 94, for example formed from TEFLON®, is positioned as required between: (1) the skirt inductor foot 12a, skirt inductor leg 12b and skirt coil 12c; and (2) the crown inductor foot 14a, crown inductor leg 14b and crown coil 14c to provide a means of electrical isolation between skirt inductor 12 and crown inductor 14. Any other type of insulating material (dielectric), including air, can be used in other embodiments of the invention to provided electrical isolation between the skirt and crown inductor.
In this embodiment of the invention first 16 and second 18 inductor frames are each formed from a non-electrically conductive material such as a phenolic board or a GLASTIC® electrical insulating board.
b) illustrates in cross section in this embodiment of the invention, inner skirt and crown concentrators 12d and 14d respectively; skirt and crown center plugs 12e and 14e respectively; and skirt and crown coils 12c and 14c respectively. The inner skirt and crown concentrators as shown in
b) illustrates in cross section in this embodiment of the invention, electrical insulating material 92a and 92b electrically separating skirt inductor foot 12a from crown inductor foot 14a.
Assembly of the first and second workpiece inductors and the first and second inductor frames can be, for example, by bolted (or other suitable fastening means) construction.
In this embodiment of the invention
In this embodiment of the invention skirt inductor coil 12c and crown inductor coil 14c are recessed respectively in skirt inductor frame 16 and crown inductor frame 18 as indicated by frame recess regions 16a and 18a, for example in
In some applications of the present invention the geometry of either workpiece can be non-uniform and have substantial changes in mass at various radial quadrants of the workpiece. These changes in mass create heat imbalances during heating. To compensate for this, the heating surfaces of the respective inductor coil section can be profiled in angular radial quadrants to form a profiled section or region correlating to the different workpiece quadrants of varying mass. The workpiece must then be placed in the induction heating position at a specified orientation to maintain the desired inductor coil section to workpiece relationship.
Inductor assembly 10 can be connected to actuator apparatus that moves the inductor assembly into the heat position between the first and second workpieces (shown in
The actuator apparatus is illustrated in one embodiment of the invention in
Secondary magnetic device 32b is electrically connected to secondary output electrical conductors 88a and 88b. The secondary magnetic device and secondary output electrical conductors are connected to a suitable extraction actuator (not shown in the drawings) which in this embodiment moves the secondary magnetic device and secondary output electrical conductors linearly in the plus or minus Z direction as further described below. In other embodiments of the invention the extraction movement may be in another linear direction, a rotational direction or a combination of linear and rotational directions.
a) through
Optional cooling fluid medium cables 84a and 84b and 84c and 84d supply and return a cooling fluid medium to the skirt and crown inductors via the extraction assembly in this example.
In
If the first or second workpiece has one or more coil facing protrusions that would prevent retraction of the inductor assembly, a depressed coil region in a coil planar face, such as V-notches 99 shown in
In this example first inductor coil section 12c has profiled regions, for example, at the top of the coil that are profiled (contoured) regions 99′ in the X-direction (that is, the height of the induction coil section). Regions 99′ are raised above the normal face heating plane of coil section 12c on either side of V-notches 99 to compensate for low induced heat in the regions of the coil V-notches. Such profiling can be used to conform to the face of the coil section adjacent to the face of the workpiece being heated. In other examples of the invention the first and second coil sections may be of other shapes and contours to suit the shape of the corresponding first and second workpieces to heat each workpiece by proximity heating.
In this embodiment of the invention, in order to improve the heat uniformity in the transition regions 98 (
In the above method electromagnetic coupling between primary magnetic device 32a and secondary magnetic device 32b allows the inductor to retract radially (Z-direction) away from the workpieces. For example, in this embodiment the secondary magnetic device may be slidably mounted adjacent to a stationary primary magnetic device so that the secondary magnetic device can be slid downwards relative to the primary magnetic device. There is no physical contact between the primary and secondary devices which allows the secondary half that forms an electrically closed-loop circuit, with the double-sided inductor attached, to be quickly extended to the induction heating position and retracted to the induction post-heat extraction position. This is diagrammatically illustrated in circuit
Each primary magnetic device can be any device that creates a magnetic flux from an alternating current flow through the device and each secondary magnetic device can be any device that magnetically couples the primary alternating magnetic flux for power transfer between the primary and secondary magnetic devices via transformer coupling without there being a physical connection between the primary magnetic devices and the secondary magnetic devices. For example in one embodiment of the invention each primary and secondary magnetic device can be two joined magnetic C-cores to form a rectangular closed magnetic core with a central opening in which a portion of electrical conductors 86a, 86b, 88a or 88b are placed so that when alternating current flows through primary supply electrical conductors 86a and 86b a magnetic flux field is created that couples with the corresponding secondary magnetic device when extraction assembly 30 has positioned the inductors in the inductor assembly in the induction heating position. Each primary and secondary magnetic device may also be referred to as a coil wound core.
The terms skirt and crown are used interchangeably herein with other pairs of workpieces where it is advantageous to simultaneously induction heat the two workpieces. Further the process following the simultaneous heating may be joining the opposing faces of the workpieces together, but is not limited to that process as long as the process can benefit from the simultaneous induction heating.
The extraction assembly of the present invention may be used with other configurations and quantity of inductors in an induction assembly in industrial processes where high speed transfer of the inductor assembly from an induction heating position to a workpiece non-interference position where the workpiece can be further processed is desirable.
While the described embodiment of the present example uses a pair of three turn coils in series in other embodiments the number of coil turns can be singular or any multiple number of turns. In other embodiments the number of coil turns may be different for each coil in the pair of coils.
In the description above, for the purposes of explanation, numerous specific requirements and several specific details have been set forth in order to provide a thorough understanding of the example and embodiments. It will be apparent however, to one skilled in the art, that one or more other examples or embodiments may be practiced without some of these specific details. The particular embodiments described are not provided to limit the invention but to illustrate it.
Reference throughout this specification to “one example or embodiment,” “an example or embodiment,” “one or more examples or embodiments,” or “different example or embodiments,” for example, means that a particular feature may be included in the practice of the invention. In the description various features are sometimes grouped together in a single example, embodiment, figure, or description thereof for the purpose of streamlining the disclosure and aiding in the understanding of various inventive aspects.
The present invention has been described in terms of preferred examples and embodiments. Equivalents, alternatives and modifications, aside from those expressly stated, are possible and within the scope of the invention.
This application claims the benefit of U.S. Provisional Application No. 61/968,657, filed Mar. 21, 2014, hereby incorporated by reference in its entirety.
Number | Date | Country | |
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61968657 | Mar 2014 | US |