US2678994A - High-frequency power control device - Google Patents
High-frequency power control device Download PDFInfo
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- US2678994A US2678994A US218321A US21832151A US2678994A US 2678994 A US2678994 A US 2678994A US 218321 A US218321 A US 218321A US 21832151 A US21832151 A US 21832151A US 2678994 A US2678994 A US 2678994A
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- H—ELECTRICITY
- H05—ELECTRIC TECHNIQUES NOT OTHERWISE PROVIDED FOR
- H05B—ELECTRIC HEATING; ELECTRIC LIGHT SOURCES NOT OTHERWISE PROVIDED FOR; CIRCUIT ARRANGEMENTS FOR ELECTRIC LIGHT SOURCES, IN GENERAL
- H05B6/00—Heating by electric, magnetic or electromagnetic fields
- H05B6/02—Induction heating
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- This invention relates to a high-frequency power control device and is concerned more particularly with an apparatus for automatically controlling the application of a high-frequency field to a workpiece in accordance with motion imparted to one of the electrodes to position such electrode in proper predetermined relationship with respect to the workpiece.
- the application of the field to the workpiece is so controlled that any voltage surge in the output of the oscillaator or other high-frequency current generator which may be occasioned is not transmitted to the workpiece or to the electrodes.
- the heating of the workpiece may be efiected at or close to maximumpower input without any serious arcing problem.
- This may be accomplished by providing a movable electrode and inductively coupling the load to the oscillator by a coupilng coil connected to the electrodes and movable with the movable electrode from a position where the coupling is negligible to a position where close and efficient coupling is obtained.
- the high-frequency current generator may be controlled in accordance with movement of the movable electrode such as through a contactor in the plate circuit of the generator. It is not necessary, however, to interrupt the operation of the generator; and the same may be operated continuously, and control of the application of the field to the load may be controlled through movement of the coupling coil.
- An object of the invention is to provide an automatic control for high-frequency heating systems which will eliminate the need for switches, relays, or other similar control devices customarily employed.
- Another object of the invention is to provide a high-frequency power control device which is provided with an inductive coupling arrangement for effecting control of the application of the high-frequency field to the workpiece only when the workpiece and electrodes are in proper relationship for effective use of the high-frequency field upon the workpiece.
- An additional object of the invention is to provide a control for the high-frequency input to the workpiece which will be substantially free of initial transient voltages,. permitting the use of a greater field intensity without danger of arcing or other deleterious action.
- Figure 1 is a perspective view of a cone-gluing machine having a high-frequency heating unit incorporating the control device of the present invention
- Figure 2' is a top plan view of the control unit mounted within a shielding container, the top having been removed to show the details of the control mechanism;
- Figures 3 and 4 are diagrammatic views illustrating operative and inoperative positions of the control mechanism
- Figure 5 is a detailed sectional view to an enlarged scale showing the connection of one of the electrodes to the control device.
- Figure 6 is a diagrammatic sectional view illustrating the positioning of the workpiece with respect to the movable electrode.
- Figure 1 illustrates a device for the gluing of .a piece of cork composition into a hollow cone used in the textile industry.
- This is a typical embodiment of a fabricating operation requiring close control of high-frequency input to the workpiece and is typical of many embodiments in which the present invention may be employed.
- the details of the structure which supports the workpiece during the formation of the cone and during the setting of the adhesive which bonds the piece into cone formation are not important insofar as the present invention is concerned.
- Conventional equipment has been shown in Fig ure 1 for performing such operations.
- the arrangement includes a table or platform 2 upon which is mounted a pair of tracks 3. Mounted for reciprocatory motion on the tracks 3 is a carriage 4 having wheels 5 which ride on the tracks 3.
- the carriage 4 is provided with a cavity 6 shown in dotted lines in Figure 1, and the workpiece 1 is disposed within that cavity by a machine operator.
- a mold member 8 which has a cavity 9 complementary to the cavity 6 which, when juxtaposed with respect to the cavity 6, forms the workpiece I into a truncated cone, with the edges [0 and H thereof lying in abutting engagement.
- mechanism for reciprocating the carriage 4 with respect to the mold member 8.
- this includes an operating handle l2 and linkage arrangement [3.
- edges In and H of the workpiece l are coated with an adhesive, and this adhesive may be dried if it is of the solvent type or may be cooled if it is applied in melted condition prior to cone formation.
- a conventional phenolformaldehyde resin adhesive will be considered typical for purposes of-desci'ibing an embodiment of the invention.
- the adhesive dissolved in a solvent is applied to the edges which are to be joined, and the solvent is permitted to evaporate and the adhesive to dry.
- the sheets carrying dried adhesive on the edges to be joined are supplied to the machine operator who inserts an individual sheet in the cavity 8, moves the handle l2 in a clockwise direction, thus bringing the carriage 4 into position under the mold cavity 8, and automatically forms the workpiece 1 into a truncated cone shape, with the edges 10 and l I in abutting engagement as shown in Figure 6.
- the mold member 8 is preferably heated to about 230 F. to avoid heat loss for the workpiece l to the walls of the mold member 8. This may be accomplished by providing an electric strip heater S mounted on the side of the mold member 8 as shown in Figure l.
- the adhesive disposed at the zone of juncture is then activated by the appli cation of heat, and the carriage is retracted to the position shown in Figure l, by operation of the handle l2 in a counterclockwise direction.
- An arrangement is shown in the drawings for the dielectric heating of the adhesive to activate the same and includes a movable electrode 14 which is adapted to be disposed within the workpiece I closely adjacent to and preferably in contact therewith at the glue line or closely adjacent to it.
- the stationary mold member 8 is preferably made of a good electrical conductor such as brass or bronze; it constitutes a second electrode.
- a removable insert 16 is provided in the stationary mold member, disposed at the glue line.
- the movable electrode 14 is of a length sufficient to extend throughout the whole of the glue line to be activated; and, of
- the mold member 8 constituting the other electrode is of a depth to receive the whole of the workpiece.
- the movable electrode I4 is mounted upon a coaxial feeder including a sleeve H which has fastened theretoa cup-shaped 4 coupling member [8 into which is inserted an insulating ring I9 and an insulating disc 2 Electrode I4 is provided with a iiange 2i and a projecting stem 22 which is encircled by an in sulating washer 23. ihe opposite end of the sleeve 6'! receives a connector 24 which is provided. with a recess 25 which receives one of a pair of insulating washers 23. A threaded rod 21 is received within a threaded opening 28 in the electrode l4, and the opposite threaded end 29 of the rod 2?
- is made with the electrode [4 through the rod 2'! and the clamping nut 38.
- a second electrical connection 32 is made to the connector 24.
- the connections 3! and 32 extend to a coil 33 which may be constituted of hollow copper tubing and may have a single turn or slightly more than a single turn as shown in Figures 3 and 4.
- the sleeve I1 is mounted in bearings 34 and 35 for reciprocatory motion to bring the electrode l4 into proper relationship with respect to the workpiece and to remove the same from the zone of the workpiece upon completion of the heating.
- an operating handle 36 is provided which may be grasped by the workman and pulled to bring the electrode to the position shown in Figure 3 to effect heating or pushed to retract the electrode to the position shown in Figure 4 upon completion of the heating cycle.
- a stationary coupling coil 38 mounted within a shielding receptacle 31 is a stationary coupling coil 38 connected to a source of high-frequency power 39 indicated diagrann matically in Figure l.
- a one-half kilowatt vacuum tube oscillator operating at a frequency of forty megacycles will be acceptable.
- a variable condenser 40 may be provided in the shielding container to tune the coupling circuit externally of the high-frequency generator.
- the coil 38 may be formed of copper tubing similar to the coil 33, and its axis is preferably coincident with the axis of coil 33.
- the coil 38 is so positioned that, when the electrode i4 is in proper relationship with the workpiece l, the coil 33 will be disposed in efilcient inductive relationship with respect to the coil 38 so that the power from the high-frequency source, such as the oscillator 39, will be supplied to the electrode 14.
- the coil 38 constitutes slightly more than a single turn. The number of turns in the coils 33 and 38 will be such to obtain the desired impedance match in the inductively coupled circuits, determined by the frequency at which the system is to operate.
- the coils 3-3 and 33 will be out of inductive relationship to such an extent that no substantial high-frequency voltage will be present on the movable electrode I4; and thus the entire heating operation willbe effected only when the electrode i4 is disposed fully within the workpiece.
- the electrode i4 is at high potential; and the other electrode, the stationary mold member 8, connected by a flexible strap 4
- Power is received by the coil 33 and is transmitted through the coaxial feeder to the electrode system comprising movable electrode :4 and stationary electrode 8.
- the workpiece with its adhesive line disposed between the electrodes 8 and I4 is heated when the electrode 14 is moved into proper posttion, bringing the coils 33 and 38 into eflicient inductive relationship.
- a microswitch 42 may be provided on. the machine to be actuated by a control cam is on the actuator arm 36 for moving the electrode it. This switch may control the plate contactor of the oscillator to energize the coil 38 as the coil 33 approaches coil 38 and to deenergize coil 38 as coil 33 recedes therefrom.
- a source of highfrequency alternating electric voltage comprising a stationary coil, a movable coil, means electrically coupling said stationary coil to said source of voltage, and means electrically coupling said movable coil to said stationary electrode and to said movable electrode for the transfer to said electrodes of current induced in said movable coil from said stationary coil coupled to said source; and means for controlling the coupling of said electrodes to said source in accordance with movement of said movable electrode to an operative position comprising means mechanically connecting said movable coil to said movable electrode for movement in unison therewith and means for coincidentally moving said movable coil and said movable electrode to shift said movable coil with respect to said stationary coil from an inoperative position to an operative position in efficient inductive coupling relationship with said stationary coil to inductively couple said electrodes to said source and simultaneously to shift
- a source of highfrequency alternating electric voltage comprising a stationary coil, a movable coil, means electrically coupling said stationary coil to said source of voltage, and a coaxial feeder electrically coupling said movable coil to said stationary electrode and to said movable electrode for the transfer to said electrodes of current induced in said movable coil from said stationary coil coupled to said source; and means for controlling the coupling of said electrodes to said source in accordance with movement of said movable electrode to an operative position comprising means mechanical- 1y connecting said movable coil to said movable electrode for movement in unison therewith and meansengageable with said coaxial feeder for coincidentally moving said movable coil and said movable electrode to shift said movable coil with respect to said stationary coil from an inoperative position to an operative position in eflicient inductive coupling relationship with
- a source of highfrequency alternating electric voltage comprising a stationary coil, a movable coil, means electrically coupling said stationary coil to said source of voltage, and a coaxial feeder comprising an outer tubular conductor electrically coupled to said stationary electrode and an inner conductor electrically coupled to said movable electrode for the transfer to said electrodes of current induced in said movable coil from said stationary coil coupled to said source; and means for controlling the coupling of said electrodes to said source in accordance with movement of said movable electrode to an operative position comprising means mechanically connecting said movable coil to said movable electrode for movement in unison therewith and means for coincidentally moving said movable coil and said movable electrode to shift said movable coil with respect to said stationary coil from an inoperative position to an operative position in efiicient inductive coup
- a pair of electrodes relatively movable from an operative position where the field established between said electrodes will embrace said workpiece to an inoperative position; means for inductively coupling said electrodes to a source of high-frequency alternating electric voltage comprising a stationary coil, a movable coil, means electrically coupling said stationary coil to said source of voltage, and means electrically coupling said movable coil to said stationary electrode and to said movable electrode for the transfer to said electrodes of current induced in said movable coil from said stationary coil coupled to said source; means for relatively moving said electrodes from said inoperative position to said operative position; and means responsive to said relative movement of said electrodes for varying said inductive coupling of said electrodes to said source to gradually increase the coupling as said electrodes reach said operative position.
- a pair of electrodes relatively movable from an operative position where the field established between said elec-- trodes will embrace said workpiece to an inop- ,7, erative.
- positiom meansfor inductively COIlDling said electrodes to a source of high-frequency alternating.
- electric voltage comprising a stationary coil a movable coil, means electrically coupling, said stationary coil to said source of voltage, and means electrically coupling said movable coil to said stationary electrode and to said movable electrode for the transfer to said electrodes of current induced in said movable coil from said stationary coil coupled to said source; means for relatively moving said elec trodes from said inoperative position to said operative position; and means carried by said mov-- ing.
- a device for dielectrically heating a workpiece disposed between a pair of electrodes to which there is supplied a highdrequency alternating. electric voltage from a source thereof the combination of a stationary coil connected to said source, a movable coil connected to said electrodes, a switch for controlling the output of said voltage from said source to said stationary'coil, means for moving said movable coil from an inoperative position to an operative position in efficient inductive coupling relationship with said stationary coil, and means carried by said moving means for controlling said switch to energize said stationary coil as said movable coil approaches said operative position with respect thereto.
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- Lining Or Joining Of Plastics Or The Like (AREA)
Description
y 18, 1954 w. RUEGGEBERG HIGH-FREQUENCY POWER CONTROL DEVICE Filed March 30, 1951 2 Sheets-Sheet l INVENTOR WERNER RUEGGEBERG ATTORNEY May 18, 1 w. RUEGGEBERG 2,678,994
HIGH-FREQUENCY POWER CONTROL DEVICE Filed March 30, 1951 2 Sheets-Sheet 2 A /E- V//////////////////A/ ,Y H
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1N VENTOR WERNER RU EGGEBERG ATTORNEY Patented May 18, 1954 HIGH-FREQUENCY POWER CONTROL DEVICE Werner Rueggeberg, Lancaster, Pa., assignor to Armstrong Cork Company, Lancaster, Pa., a corporation of Pennsylvania Application March 30, 1951, Serial No. 218,321
6 Claims.
This invention relates to a high-frequency power control device and is concerned more particularly with an apparatus for automatically controlling the application of a high-frequency field to a workpiece in accordance with motion imparted to one of the electrodes to position such electrode in proper predetermined relationship with respect to the workpiece.
In the manufacture of articles having a small wall thickness, there is present the problem of avoiding arcing between the electrodes under high stress. In the edge gluing of cork compositions, such as in the manufacture of cones used in the textile industry where pieces of cork about one-eighth of an inch thick are bent into cone shape and the abutting edges of the pieces are adhesively joined, the use of high-frequency dielectric heating to activate the adhesive has presented the problem of preventing arcing between the closely spaced electrodes. As is well known, when the electrodes are properly positioned adjacent to the glue line to be activated and the field is applied as by closing a switch energizing the plate circuit of the oscillator, there is an instantaneous build-up or surge of voltage applied between the electrodes, often above the normal or constant voltage applied to the workpiece. This surge may be well above the normal input and may be beyond the puncture point of the workpiece, resulting in arcing between the electrodes and damage to or destruction of the workpiece for its intended purpose. To overcome this, it has been necessary to reduce the voltage applied to the workpiece to a value where the surge is below the range where arcing will occur; but this of course reduces the heating rate, and maximum efficiency of operation is not obtained.
According to the present invention, the application of the field to the workpiece is so controlled that any voltage surge in the output of the oscillaator or other high-frequency current generator which may be occasioned is not transmitted to the workpiece or to the electrodes. Thus the heating of the workpiece may be efiected at or close to maximumpower input without any serious arcing problem. This may be accomplished by providing a movable electrode and inductively coupling the load to the oscillator by a coupilng coil connected to the electrodes and movable with the movable electrode from a position where the coupling is negligible to a position where close and efficient coupling is obtained. If desired, the high-frequency current generator may be controlled in accordance with movement of the movable electrode such as through a contactor in the plate circuit of the generator. It is not necessary, however, to interrupt the operation of the generator; and the same may be operated continuously, and control of the application of the field to the load may be controlled through movement of the coupling coil.
.An object of the invention is to provide an automatic control for high-frequency heating systems which will eliminate the need for switches, relays, or other similar control devices customarily employed.
Another object of the invention is to provide a high-frequency power control device which is provided with an inductive coupling arrangement for effecting control of the application of the high-frequency field to the workpiece only when the workpiece and electrodes are in proper relationship for effective use of the high-frequency field upon the workpiece.
An additional object of the invention is to provide a control for the high-frequency input to the workpiece which will be substantially free of initial transient voltages,. permitting the use of a greater field intensity without danger of arcing or other deleterious action.
Other objects of the invention will be apparent from consideration of the following description of an embodiment of the invention illustrated in the attached drawings, in which:
Figure 1 is a perspective view of a cone-gluing machine having a high-frequency heating unit incorporating the control device of the present invention;
Figure 2' is a top plan view of the control unit mounted within a shielding container, the top having been removed to show the details of the control mechanism;
Figures 3 and 4 are diagrammatic views illustrating operative and inoperative positions of the control mechanism;
Figure 5 is a detailed sectional view to an enlarged scale showing the connection of one of the electrodes to the control device; and
Figure 6 is a diagrammatic sectional view illustrating the positioning of the workpiece with respect to the movable electrode.
Figure 1 illustrates a device for the gluing of .a piece of cork composition into a hollow cone used in the textile industry. This is a typical embodiment of a fabricating operation requiring close control of high-frequency input to the workpiece and is typical of many embodiments in which the present invention may be employed. The details of the structure which supports the workpiece during the formation of the cone and during the setting of the adhesive which bonds the piece into cone formation are not important insofar as the present invention is concerned. Conventional equipment has been shown in Fig ure 1 for performing such operations. The arrangement includes a table or platform 2 upon which is mounted a pair of tracks 3. Mounted for reciprocatory motion on the tracks 3 is a carriage 4 having wheels 5 which ride on the tracks 3. The carriage 4 is provided with a cavity 6 shown in dotted lines in Figure 1, and the workpiece 1 is disposed within that cavity by a machine operator. Mounted above the carriage 4 is a mold member 8 which has a cavity 9 complementary to the cavity 6 which, when juxtaposed with respect to the cavity 6, forms the workpiece I into a truncated cone, with the edges [0 and H thereof lying in abutting engagement. In
order to bring the two parts 4 and 8 into such position, mechanism is provided for reciprocating the carriage 4 with respect to the mold member 8. In the embodiment shown, this includes an operating handle l2 and linkage arrangement [3.
The edges In and H of the workpiece l are coated with an adhesive, and this adhesive may be dried if it is of the solvent type or may be cooled if it is applied in melted condition prior to cone formation. A conventional phenolformaldehyde resin adhesive will be considered typical for purposes of-desci'ibing an embodiment of the invention. The adhesive dissolved in a solvent is applied to the edges which are to be joined, and the solvent is permitted to evaporate and the adhesive to dry. The sheets carrying dried adhesive on the edges to be joined are supplied to the machine operator who inserts an individual sheet in the cavity 8, moves the handle l2 in a clockwise direction, thus bringing the carriage 4 into position under the mold cavity 8, and automatically forms the workpiece 1 into a truncated cone shape, with the edges 10 and l I in abutting engagement as shown in Figure 6. The mold member 8 is preferably heated to about 230 F. to avoid heat loss for the workpiece l to the walls of the mold member 8. This may be accomplished by providing an electric strip heater S mounted on the side of the mold member 8 as shown in Figure l. The adhesive disposed at the zone of juncture is then activated by the appli cation of heat, and the carriage is retracted to the position shown in Figure l, by operation of the handle l2 in a counterclockwise direction.
An arrangement is shown in the drawings for the dielectric heating of the adhesive to activate the same and includes a movable electrode 14 which is adapted to be disposed within the workpiece I closely adjacent to and preferably in contact therewith at the glue line or closely adjacent to it. The stationary mold member 8 is preferably made of a good electrical conductor such as brass or bronze; it constitutes a second electrode. To facilitate cleaning of any excesive adhesive which may be extruded at the joint, a removable insert 16 is provided in the stationary mold member, disposed at the glue line. The movable electrode 14 is of a length sufficient to extend throughout the whole of the glue line to be activated; and, of
course, the mold member 8, constituting the other electrode, is of a depth to receive the whole of the workpiece.
As shown in Figure 5, the movable electrode I4 is mounted upon a coaxial feeder including a sleeve H which has fastened theretoa cup-shaped 4 coupling member [8 into which is inserted an insulating ring I9 and an insulating disc 2 Electrode I4 is provided with a iiange 2i and a projecting stem 22 which is encircled by an in sulating washer 23. ihe opposite end of the sleeve 6'! receives a connector 24 which is provided. with a recess 25 which receives one of a pair of insulating washers 23. A threaded rod 21 is received within a threaded opening 28 in the electrode l4, and the opposite threaded end 29 of the rod 2? receives a clamping nut 39 which clamps the various parts of the electrode structure into rigid relationship. An electrical connection 3| is made with the electrode [4 through the rod 2'! and the clamping nut 38. A second electrical connection 32 is made to the connector 24. The connections 3! and 32 extend to a coil 33 which may be constituted of hollow copper tubing and may have a single turn or slightly more than a single turn as shown in Figures 3 and 4.
The sleeve I1 is mounted in bearings 34 and 35 for reciprocatory motion to bring the electrode l4 into proper relationship with respect to the workpiece and to remove the same from the zone of the workpiece upon completion of the heating. In the embodiment illustrated, an operating handle 36 is provided which may be grasped by the workman and pulled to bring the electrode to the position shown in Figure 3 to effect heating or pushed to retract the electrode to the position shown in Figure 4 upon completion of the heating cycle.
Mounted within a shielding receptacle 31 is a stationary coupling coil 38 connected to a source of high-frequency power 39 indicated diagrann matically in Figure l. A one-half kilowatt vacuum tube oscillator operating at a frequency of forty megacycles will be acceptable. A variable condenser 40 may be provided in the shielding container to tune the coupling circuit externally of the high-frequency generator. The coil 38 may be formed of copper tubing similar to the coil 33, and its axis is preferably coincident with the axis of coil 33. The coil 38 is so positioned that, when the electrode i4 is in proper relationship with the workpiece l, the coil 33 will be disposed in efilcient inductive relationship with respect to the coil 38 so that the power from the high-frequency source, such as the oscillator 39, will be supplied to the electrode 14. The coil 38 constitutes slightly more than a single turn. The number of turns in the coils 33 and 38 will be such to obtain the desired impedance match in the inductively coupled circuits, determined by the frequency at which the system is to operate. When the electrode i4 is moved to the inoperative position shown in Figure 4, the coils 3-3 and 33 will be out of inductive relationship to such an extent that no substantial high-frequency voltage will be present on the movable electrode I4; and thus the entire heating operation willbe effected only when the electrode i4 is disposed fully within the workpiece.
The electrode i4 is at high potential; and the other electrode, the stationary mold member 8, connected by a flexible strap 4| to the outside conductor or sleeve I! of the coaxial feeder as shown in Figure 5 is near ground potential. Power is received by the coil 33 and is transmitted through the coaxial feeder to the electrode system comprising movable electrode :4 and stationary electrode 8. The workpiece with its adhesive line disposed between the electrodes 8 and I4 is heated when the electrode 14 is moved into proper posttion, bringing the coils 33 and 38 into eflicient inductive relationship.
As shown in Figure 1, a microswitch 42 may be provided on. the machine to be actuated by a control cam is on the actuator arm 36 for moving the electrode it. This switch may control the plate contactor of the oscillator to energize the coil 38 as the coil 33 approaches coil 38 and to deenergize coil 38 as coil 33 recedes therefrom. Re-
gardless of whether the high-frequency current generator be operated continuously or its output controlled in the manner described above or some other manner, there will be a gradual build-up of voltage at the electrodes as the coil 33 approaches its zone of maximum coupling with coil 38 and electrode It assumes its proper position with respect to mold electrode 8 and the workpiece 1. Any substantial voltage surge which may occur with the switching system will be at a time when the coils 33 and 38 are outof efiicient coupling relationship; and, consequently, the power input to the electrodes will not approach the arcing stage, although the high--frequency generator may be supplying abnormally high voltages to coil 33.
I claim: V
1. In a device for dielectrically heating a workpiece, the combination of a source of highfrequency alternating electric voltage; a stationary electrode; a movable electrode; means for inductively coupling said electrodes to said source of voltage comprising a stationary coil, a movable coil, means electrically coupling said stationary coil to said source of voltage, and means electrically coupling said movable coil to said stationary electrode and to said movable electrode for the transfer to said electrodes of current induced in said movable coil from said stationary coil coupled to said source; and means for controlling the coupling of said electrodes to said source in accordance with movement of said movable electrode to an operative position comprising means mechanically connecting said movable coil to said movable electrode for movement in unison therewith and means for coincidentally moving said movable coil and said movable electrode to shift said movable coil with respect to said stationary coil from an inoperative position to an operative position in efficient inductive coupling relationship with said stationary coil to inductively couple said electrodes to said source and simultaneously to shift said movable electrode with respect to said stationary electrode from an inoperative position to an operative position where the field established between said electrodes through efficient inductive coupling of said coils will embrace said workpiece.
2. In a device for dielectrically heating a workpiece, the combination of: a source of highfrequency alternating electric voltage; a stationary electrode; a movable electrode; means for inductively coupling said electrodes to said source of voltage comprising a stationary coil, a movable coil, means electrically coupling said stationary coil to said source of voltage, and a coaxial feeder electrically coupling said movable coil to said stationary electrode and to said movable electrode for the transfer to said electrodes of current induced in said movable coil from said stationary coil coupled to said source; and means for controlling the coupling of said electrodes to said source in accordance with movement of said movable electrode to an operative position comprising means mechanical- 1y connecting said movable coil to said movable electrode for movement in unison therewith and meansengageable with said coaxial feeder for coincidentally moving said movable coil and said movable electrode to shift said movable coil with respect to said stationary coil from an inoperative position to an operative position in eflicient inductive coupling relationship with said stationary coil to inductively couple said electrodes to said source and simultaneously to shift said movable electrode with respect to said stationary electrode from an inoperative position to an operative position where the field established between said electrodes through efficient inductive coupling of said coils will embrace said workpiece.
3.. In a device for dielectrically heating a workpiece, the combination of: a source of highfrequency alternating electric voltage; a stationary electrode; a movable electrode; means for inductively. coupling said electrodes to said source of voltage comprising a stationary coil, a movable coil, means electrically coupling said stationary coil to said source of voltage, and a coaxial feeder comprising an outer tubular conductor electrically coupled to said stationary electrode and an inner conductor electrically coupled to said movable electrode for the transfer to said electrodes of current induced in said movable coil from said stationary coil coupled to said source; and means for controlling the coupling of said electrodes to said source in accordance with movement of said movable electrode to an operative position comprising means mechanically connecting said movable coil to said movable electrode for movement in unison therewith and means for coincidentally moving said movable coil and said movable electrode to shift said movable coil with respect to said stationary coil from an inoperative position to an operative position in efiicient inductive coupling relationship with said stationary coil to inductively couple said electrodes to said source and simultaneously to shift said movable electrode with respect to said stationary electrode from an inoperative position to an operative position where the field established between said electrodes through efficient inductive coupling of said coils will embrace said workpiece.
4. In a device for dielectrically heating a workpiece, the combination of: a pair of electrodes relatively movable from an operative position where the field established between said electrodes will embrace said workpiece to an inoperative position; means for inductively coupling said electrodes to a source of high-frequency alternating electric voltage comprising a stationary coil, a movable coil, means electrically coupling said stationary coil to said source of voltage, and means electrically coupling said movable coil to said stationary electrode and to said movable electrode for the transfer to said electrodes of current induced in said movable coil from said stationary coil coupled to said source; means for relatively moving said electrodes from said inoperative position to said operative position; and means responsive to said relative movement of said electrodes for varying said inductive coupling of said electrodes to said source to gradually increase the coupling as said electrodes reach said operative position.
5. In a device for dielectrically heating a workpiece, the combination oi: a pair of electrodes relatively movable from an operative position where the field established between said elec-- trodes will embrace said workpiece to an inop- ,7, erative. positiom, meansfor inductively COIlDling said electrodes to a source of high-frequency alternating. electric voltage comprising a stationary coil a movable coil, means electrically coupling, said stationary coil to said source of voltage, and means electrically coupling said movable coil to said stationary electrode and to said movable electrode for the transfer to said electrodes of current induced in said movable coil from said stationary coil coupled to said source; means for relatively moving said elec trodes from said inoperative position to said operative position; and means carried by said mov-- ing. means for controlling the application of said source to said inductive coupling means and also for varying said inductive coupling of said electrode to said source to gradually increase the coupling and the intensity of the field established between said electrodes as said electrodes reach said operative position.
6.- In a device for dielectrically heating a workpiece disposed between a pair of electrodes to which there is supplied a highdrequency alternating. electric voltage from a source thereof, the combination of a stationary coil connected to said source, a movable coil connected to said electrodes, a switch for controlling the output of said voltage from said source to said stationary'coil, means for moving said movable coil from an inoperative position to an operative position in efficient inductive coupling relationship with said stationary coil, and means carried by said moving means for controlling said switch to energize said stationary coil as said movable coil approaches said operative position with respect thereto.
References Cited in the file of this patent UNITED STATES PATENTS
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US218321A US2678994A (en) | 1951-03-30 | 1951-03-30 | High-frequency power control device |
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US218321A US2678994A (en) | 1951-03-30 | 1951-03-30 | High-frequency power control device |
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US2678994A true US2678994A (en) | 1954-05-18 |
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Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2797289A (en) * | 1955-02-21 | 1957-06-25 | Int Harvester Co | Induction heating device for treating cylinder bores |
Citations (8)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2109323A (en) * | 1937-07-08 | 1938-02-22 | Compo Shoe Machinery Corp | Shoe cementing apparatus |
GB556292A (en) * | 1942-07-23 | 1943-09-28 | Rediffusion Ltd | Improvements in and relating to high frequency electric heating apparatus |
US2401991A (en) * | 1942-02-25 | 1946-06-11 | British Insulated Cables Ltd | Machine for compressing and heating electrically thermoplastic materials |
US2467782A (en) * | 1947-09-20 | 1949-04-19 | Westinghouse Electric Corp | Dielectric heating means with automatic compensation for capacitance variation |
US2504956A (en) * | 1946-05-31 | 1950-04-25 | Girdler Corp | Combined heating electrodes and variable capacitor for dielectric heating |
US2516324A (en) * | 1946-02-15 | 1950-07-25 | Rca Corp | Constant potential gradient dielectric heating device |
US2519193A (en) * | 1946-11-02 | 1950-08-15 | Operadio Mfg Company | High-frequency heating system |
US2572226A (en) * | 1947-04-24 | 1951-10-23 | Raytheon Mfg Co | Welding of thermoplastic materials with application of highfrequency dielectric energy and pressure |
-
1951
- 1951-03-30 US US218321A patent/US2678994A/en not_active Expired - Lifetime
Patent Citations (8)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2109323A (en) * | 1937-07-08 | 1938-02-22 | Compo Shoe Machinery Corp | Shoe cementing apparatus |
US2401991A (en) * | 1942-02-25 | 1946-06-11 | British Insulated Cables Ltd | Machine for compressing and heating electrically thermoplastic materials |
GB556292A (en) * | 1942-07-23 | 1943-09-28 | Rediffusion Ltd | Improvements in and relating to high frequency electric heating apparatus |
US2516324A (en) * | 1946-02-15 | 1950-07-25 | Rca Corp | Constant potential gradient dielectric heating device |
US2504956A (en) * | 1946-05-31 | 1950-04-25 | Girdler Corp | Combined heating electrodes and variable capacitor for dielectric heating |
US2519193A (en) * | 1946-11-02 | 1950-08-15 | Operadio Mfg Company | High-frequency heating system |
US2572226A (en) * | 1947-04-24 | 1951-10-23 | Raytheon Mfg Co | Welding of thermoplastic materials with application of highfrequency dielectric energy and pressure |
US2467782A (en) * | 1947-09-20 | 1949-04-19 | Westinghouse Electric Corp | Dielectric heating means with automatic compensation for capacitance variation |
Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2797289A (en) * | 1955-02-21 | 1957-06-25 | Int Harvester Co | Induction heating device for treating cylinder bores |
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