US2902575A - Electric glassworking - Google Patents

Electric glassworking Download PDF

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US2902575A
US2902575A US762171A US76217158A US2902575A US 2902575 A US2902575 A US 2902575A US 762171 A US762171 A US 762171A US 76217158 A US76217158 A US 76217158A US 2902575 A US2902575 A US 2902575A
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arc
electrodes
workpiece
heating
current
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US762171A
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Edwin M Guyer
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Corning Glass Works
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Corning Glass Works
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    • CCHEMISTRY; METALLURGY
    • C03GLASS; MINERAL OR SLAG WOOL
    • C03BMANUFACTURE, SHAPING, OR SUPPLEMENTARY PROCESSES
    • C03B29/00Reheating glass products for softening or fusing their surfaces; Fire-polishing; Fusing of margins
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y10TECHNICAL SUBJECTS COVERED BY FORMER USPC
    • Y10STECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y10S65/00Glass manufacturing
    • Y10S65/04Electric heat

Definitions

  • the present invention relates to a method of are heating suitable for electric glassworking which is free of the limitations of those methods heretofore known, and is a division of application Serial No. 654,740, filed April 24, 1957.
  • Electric glassworking involves the transformation of electric energy into heat adjacent to or inside a glass or other dielectric workpiece. This heat may be generated by an electric are alone, or by an electric arc supplemented by the conduction of electric current through the portions of the workpiece which it is desired to heat. Since glass at room temperature is an insulator it has usually been customary, in accordance with past practice, to preheatthe workpiece to a temperature at which it becomes an electrical conductor. This requires gas flames or othervauxiliary preheating facilities, such as for example conductive coatings, which complicate and increase the cost of electric glassworking machines.
  • the foregoing disadvantages ofelectric glassworking are wholly overcome by use of two or more special are former electrodes of appropriate configurations arranged in spaced end to end relation about or along the region of the workpiece to be electrical-ly heated, and are oriented in a magnetic field whose lines of force have a component which passes at right angles, or normal to the plane of the electrodes.
  • Power is applied to the electrodes at a voltage high enough to cause an arc discharge to initially pass through one or more relatively shortgaps between the ends of adjacent electrodes.
  • the magnetic field bends each such electric are into a curve and forces part of the arc plasma stream against the workpiece surface directly opposite such gap.
  • the bent are by this action acquires a shape such that the current travels inthree different directions, namely, from the one electrode toward the workpiece surface, along such surface and from such surface toward the companion of the electrodes between which the arc was initiated. Since, however, the magnetic field lines run normal to the plane of the runner electrodes the are current moves at right angles to such lines and to its own instantaneousv direction, one part of such are advancing along each electrode while a third part of it remains anchored to the workpiece surface against which it is magnetically forced. By such action the arc stretches and presses against or wraps itself tightly around the workpiece which is thereby heated by the arc current in the zone of interception of the arc column.
  • the workpiece may be heated in the above fashion with or without the benefit of heat by electric conduction.
  • the preferred variation of the method is entirely dependent on the size, shape characteristic, or composition of the workpiece.
  • the workpiece has a coating thereon in the region adjacent that to be worked which might be damaged by conduction heating, such form of heating is avoided by maintaining the applied potential below that at which the heated glass will accept an appreciable amount of current.
  • Such method is also most appropriate when the composition of the workpiece is such that it is a poor conductor even at high temperatures, such for example as fused silica.
  • heating rates can be accelerated when arc trapping ledges can be formed, as at the junction of a seal when thick and thin section workpieces are to be joined to one another.
  • arc trapping grooves can be formed between two workpieces of substantially the same wall thickness if the meeting edge of at least one of such workpieces is bevelled back from its inner edge to provide an arc trapping groove along the line of juncture of the workpieces. Regulation of the heat input during arc flame heating can be effected by variation of the magnetic field strength.
  • the magnetic field however in which heating is taking place at all times keeps the arcs in rapid motion over the arcrunner electrodes and thus insures that the heat concentration of the arc is never such as to destroy either the surfaces of the electrodes or of the workpiece.
  • the electrodes also provide complete protection against heat loss by surface flashover in the event that the power supply exceeds the energy acceptance of the glass at any stage of the process.
  • two runner electrodes may suflice.
  • the paths are longer four or more electrodes are preferably employed.
  • the heat input may be effected by applying power to adjacent pairs of electrodes in succession, or alternatively when higher speed heating is desired; power may be concurrently applied to different groups of the electrodes to concurrently heat the respective sections of the workpiece along such path.
  • hollow electrodes may be employed, having open slots faced toward the workpiece and with such electrodes connected to a vacuum line, tocounteract the tendency for hot gases generated by the arc to rise by convection and thus aid the magnetic field in confining the are heat to a very narrow region.
  • the operation may, if desired, be further accelerated: to some. extent by application of a stripe of conductive material along the heating path. With such a. stripe present, electric conduction heating can be established. substantially immediately.
  • an arc travel and dwell type of operation is possible and may afford certain advantages under certain circumstances.
  • Such an arrangement embodies a number of arc travel stopping gates in suitable positions along the arc runner electrodes that may be operated at will to stop the arc travel or be disabled to permit resumption of the arc travel.
  • This type of operation can be obtained by association with the arc-runner electrodes .of movable conductors or gates which can be extended into closer promixity of the workpiece than are the runner electrodes to stop thearc, or be retracted to allow arc travel to be resumed, or by the use of vacuum electrodes such as disclosed in Patent No. 2,590,173 in lieu of such movable couductors.
  • Fig. 1 is a side elevation, partly in section of an apparatus suitable for practicing the invention and showing av tubular workpiece associated therewith.
  • Fig. 2 is a view taken on line 22 of Fig. 1.
  • vFig. 3 is a diagrammatic representation of the arrangement of Fig. l and of its operating circuit.
  • Fig. 4 diagrammatically illustrates an alternative form of the apparatus arranged about a workpiece which may be: of large diameter.
  • Fig.. 5 diagrammatically illustrates another form of the apparatus arranged about a workpiece and circuits for feeding power to its electrodes.
  • Fig. 6 diagrammatically illustrates the structural arrangement of Fig. 5, but with an alternative power feed system.
  • Fig. 7 diagrammatically illustrates a still further alternative arrangement and a power feed therefor.
  • Fig. 8- diagrammatically illustrates a structure employing hollow electrodes.
  • Fig. 8a is a sectional view taken on line 8a-8a of Fig. 8.
  • Fig. 9 diagrammatically illustrates the arrangement of electrodes as in Fig. 1, but with a power supply circuit especially suitable for low cost precision heat input control.
  • Fig. 10 diagrammatically illustrates an arrangement wherein the electrodes have associated therewith gates. for effecting an arc travel and dwell type of operation.
  • Figs. ll, 12 and 13 illustrate three different forms of power supply networks any which may be used with any, of the electrode arrangements shown.
  • a base 11 provided with a vertical column 12, from a lower region of which a platform 13 projects and on which is mounted a hollow core magnet 15.
  • a tube 17 of highly refractory dielectric material surrounds the magnet 15 and has an inwardly extended flange 18 that serves as a support for arc runner electrodes 19 and 20 and for an arc return conductor 21.
  • the flange 18 also serves to protect the magnet 15 from arc flames that issue between the runner electrodes 19 and 20 and a workpiece such as 25.
  • Workpiece 25 is suspended within the bore of magnet 15 from a chuck 26 attached to the lower end of a vertical shaft 27 supported from a side arm 28 projected from column 12.
  • the upper end of shaft 27 is provided with a pulley 30 by means of which the shaft may be rotated if desired, although rotation of the workpiece is not necessary.
  • a winged screw 31 is provided to lock the shaft 27 against rotation if desired.
  • Such field will bend the are into a curve that forces part of the arc stream against the surface of the workpiece 25 directly opposite gap 22.
  • the bent arc will have thus acquired, by this action,.a shape such that the. arc current will be traveling in three different directions in the three different parts of the discharge path, as shown in- Fig. 2, by the interrupted line designated by the letters a, b and 0.
  • the current is moving from are runner electrode 19 toward the workpiece, at b, it is moving along the workpiece surface, and at c it is moving from the workpiece toward arc runner electrode 20.
  • the field of magnet 15 however, has the same directionout of the plane of the diagram-at all of these points.
  • the magnetic field still keeps the arcs in rapid motion over the arc runner electrodes 19 and 20 and insures against the are destroying of either the surface of the runner electrodes or the workpiece.
  • 'Ihe electrodes also provide complete protection against heat loss by surface flashover in the event that the power supply exceeds the energy acceptance of the workpiece at any stage of the process, because the magnetic field continues to drive the arc column or plasma against the glass.
  • the input potential is merely held below that at which any substantial amount of current will be caused to flow through the heated glass and the series ballast reactance is reduced to increase the arc current.
  • the glass is then wholly heated by the current carried by the arc stretched thereabout, rather than by current flowing through it.
  • uniform heating may be assured by rotation of the workpiece or by periodically operating switch RS1 to periodically reverse the direction of current flow to the electrodes 19 and 20, or alternatively, by similarly operating switch RS2 to periodically reverse the polarity of magnet 15, to reverse the direction of arc travel.
  • Fig. 1 the glassworking operation is illustrated as applied to the severance of the workpiece 25 along the interrupted line 32 and as is obvious the lower section of the workpiece will be dropped, upon severance, onto a support 27.
  • a workpiece arranged on support 27 can be elevated into engagement with a workpiece held in chuck 26, and by appropriate control of the applied potential the two workpieces can then be sealed together by either of the described glass- Working methods.
  • arc-runner electrodes such as 41 are shown arranged about a workpiece 40'.
  • power supply brushes 42 and 43 are rotated about the electrodes to successively connect power to adjacent pairs thereof to successively heat segments of a path about the workpiece in the same fashion that the entire path about workpiece 25 is heated by power supplied to electrodes 19 and 20.
  • the same results as with rotating brushes can be obtained by using distribution switches S1S8.
  • This is accomplished by so exciting each of the arc-runner electrodes 51-54 in sequence that each is paired alternately with the one ahead of it and the one behind it to progressively scan the workpiece with a traveling arc.
  • the distribution switches S1S8 are illustrated as being operated by their associated magnets in the desired pair combinations in succession by means of a suitable step-by-step distributor switch DS.
  • circuits are closed for the magnets of switches S1 and S8 which operate and thus connect the power supply line conductors L1 and L2 to are runner electrodes 51 and 52 respectively.
  • the operating circuits for the magnets of switches S1 and S8 extend from an X terminal of a suitable current source, through wiper W, conductor 55 and through the magnet of switch S1 to a Y terminal of the same current source, and via a branch conductor 56 through the magnet of switch S8 to a second Y terminal of such current source respectively.
  • the circuit to electrode 51 extends from line L1, through conductor 57 and the contacts of switch S1.
  • the circuit to electrode 52 extends from line L2 through conductor 58 and the contacts of switch S8. Similar circuits are established to connect the leads L1 and L2 to the adjoining pairs of arc runner electrodes 52 and 54, 54 and 53 and 53 and 51 respectively in succession as switch wiper W successively engages its contacts 2, 3 and 4.
  • the different sections thereof may be desirable to simultaneously heat the different sections thereof along a path thereabout.
  • power can be separately supplied to the electrodes 51 and 52 and to 53 and 54 respectively which would eifect the simultaneous heating of the respective halves of the workpiece along a path thereabout in the same manner in which the workpiece 25 is heated by a single pair of electrodes.
  • FIG. 6 A further alternative way of simultaneously heating the respective halves of a workpiece along a path thereabout is shown in Fig. 6 wherein arc-runner electrodes 61 and 63 are connected via suitable distributor impedances, in the present instance shown as capacitors C1 and C3 to conductor 66 of a heating current source and the remaining alternately disposed electrodes 62 and 64 are connected via suitable distributor capacitors C2 and C4 to the other conductor 67 of such source.
  • arc travel occurs concurrently between the adjacent ends of the respective paired electrodes; and as in the description of the two-electrode arrangement, the arcs travel to their opposite ends while being wrapped about the adjacent section of the workpiece 68.
  • there is an arc return conductor, designated 65 which is contacted by the respective arcs which split up and return thereover to their starting points as in the preceding arrangements.
  • FIG. 7 another way of heating a large workpiece 70 is to surround it with alternately arranged active and passive runner electrodes, such as 71 through 78, and by connecting separate power sources to the electrodes 71 and 77 and to the electrodes 73 and 75' respectively.
  • active and passive runner electrodes such as 71 through 78
  • two active electrodes are to the passive electrodes and the two series connected arcs behave as in the preceding description since they circulate about their respective electrodes and return via the common arc return conductor 80.
  • Fig. 8 The arrangement of Fig. 8 is equivalent to those in Figs. 5 and 6, but the electrodes 81 to 84 are hollow, as made clear in Fig. 8a, and each has a narrow slot such as 85 along its length open toward the workpiece 86. Such electrodes are surrounded by an arc return conductor 89. Vacuum lines such as 87 are in communication with the electrodes to establish the necessary suction along the electrode slots to neutralize any thermal updraft created by the arcs, when the electrodes are arranged in a horizontal plane, as in Fig. 1. As illustrated such electrodes are also provided with passages such as 89' through which an electrode cooling medium may be circulated, from a coolant line such as 88.
  • a coolant line such as 88.
  • the heating current may be economically supplied from a 440 v. 60 cycle power supply and arc currents to insure deflection of the arc in desired directions.
  • the method of electrically heating a hard glass body along a desired path which comprises establishing an arc between the ends of electrodes spaced alongside such path, and creating a magnetic field about such path in which the magnetic lines of force are normal thereto to force the arc to travel along said electrodes in intimate contact with the glass to thereby heat it along such path.
  • a method such as defined by claim 1 which comprises concurrently creating a plurality of arcs between adjacent ends of electrodes spaced alongside such path under the influence of such magnetic lines of force to concurrently heat different sections of the glass along such path.
  • a method such as defined by claim 1 which comprises successively creating arcs between the diiferent ends of different electrodes spaced alongside such path under the influence of such magnetic lines of force to heat respective sections of the glass along such path in succession.
  • a method such as defined by claim 1 which comprises employing an electrical heating potential such that the voltage drop in the arc plasma is not sufficient to cause the arc current to transfer to the heated glass throughout the heating period.
  • a method such as defined by claim 1 which comprises employing an electric heating potential suificient to cause the arc current to fiow through the heated glass path when it attains a conductive temperature.
  • a method such as defined by claim 1 which includes starting and maintaining the arc by superimposing high frequency pilot waves on the electrodes for the heating periods.
  • a method such as defined by claim 1 which includes counteracting heat convection cu rents generated by are 10 heat to aid in restriction of the width of path in the glass heated by the arc.
  • a method such as defined by claim 1 which includes stopping the arc travel along selected regions of such path for a controlled period of time.
  • the method of working a hard glass body along an imaginary line thereon which comprises creating from an alternating current supply source an electric arc alongside thereof and parallel to a segment of such line, creating an associated magnetic field having a component that passes at right angles to such line to cause such arc to progressively extend itself under the influence of such field about the glass body, and causing the arc to separate and return to its starting point after it has been stretched for a predetermined distance about the glass body.

Description

Sept. 1, 1959 GUYER 2,902,575
ELECTRIC GLASSWORKING Original Filed April 24, 1957 I s SheetsSheet 1 INVENTOR. [DWI/V M. GUYEE Sept. 1, 1959 E. M. GUYER ELECTRIC GLASSWORKING Original Filed April 24, 1957 6 Sheets-Sheet 2 L a INVENTOR.
[OW/A M Ga YER E. M. GUYER ELECTRIC GLASSWORKING OriginaIFiled April 24, 1957 Sept. 1, 1 959 6 Sheets-Sheet 3 4 40 1/04 7 INVENTOR. 6 0 c YC fDw/N M GUYER Sept. 1, 1959 E. M. GUYER 2,902,575
ELECTRIC GLASSWORKING Original Filed April 24, 1957 6 Sheets-Sheet 4 COOL A/V7' L/lYE INVENTOR. 0 wx/v M GuYt-A Sept. 1, 1959 Original Filed April 24, 1957 E. M. GUYER 2,902,575
ELECTRIC GLASSWORKING 6 Sheets-Sheet 5 DWl/Y M GUYER United States Patent ELECTRIC GLASSWORKING Edwin M. Guyer, Corning, N.Y., assignor to Corning Glass Works, Corning, N.Y., a corporation of New York Original application April 24, 1957, Serial No. 654,740.
Divided and this application September 19, 1958, Serial No. 762,171
13 Claims. (Cl. 219-19) The present invention relates to a method of are heating suitable for electric glassworking which is free of the limitations of those methods heretofore known, and is a division of application Serial No. 654,740, filed April 24, 1957.
Electric glassworking involves the transformation of electric energy into heat adjacent to or inside a glass or other dielectric workpiece. This heat may be generated by an electric are alone, or by an electric arc supplemented by the conduction of electric current through the portions of the workpiece which it is desired to heat. Since glass at room temperature is an insulator it has usually been customary, in accordance with past practice, to preheatthe workpiece to a temperature at which it becomes an electrical conductor. This requires gas flames or othervauxiliary preheating facilities, such as for example conductive coatings, which complicate and increase the cost of electric glassworking machines. Furthermore,'the rate at which these electric conduction currents can be built up in the glass with the past electrode arrangements for electric heating is strictly limited by the so-called energy acceptance of the glass, as otherwise flashover occurs directly between the electrodes. Moreover, ordinary welding arcs as used for metal working are not suitable for working glass, because they burn up the electrodes, stain and boil the glass, and their intense heat cannot be restricted to desired patterns in the glass.
According to the invention the foregoing disadvantages ofelectric glassworking are wholly overcome by use of two or more special are former electrodes of appropriate configurations arranged in spaced end to end relation about or along the region of the workpiece to be electrical-ly heated, and are oriented in a magnetic field whose lines of force have a component which passes at right angles, or normal to the plane of the electrodes. Power is applied to the electrodes at a voltage high enough to cause an arc discharge to initially pass through one or more relatively shortgaps between the ends of adjacent electrodes. The magnetic field bends each such electric are into a curve and forces part of the arc plasma stream against the workpiece surface directly opposite such gap. The bent are by this action acquires a shape such that the current travels inthree different directions, namely, from the one electrode toward the workpiece surface, along such surface and from such surface toward the companion of the electrodes between which the arc was initiated. Since, however, the magnetic field lines run normal to the plane of the runner electrodes the are current moves at right angles to such lines and to its own instantaneousv direction, one part of such are advancing along each electrode while a third part of it remains anchored to the workpiece surface against which it is magnetically forced. By such action the arc stretches and presses against or wraps itself tightly around the workpiece which is thereby heated by the arc current in the zone of interception of the arc column. When the arc has extended itself to the opposite ends of the electrodes it bows outward at the gap between the far ends of the electrodes and is intercepted by an arc return conductor that parallels the arc runner electrodes. Upon contacting the arc return conductor the are splits up into two different parts which carry current and travel in opposite,
directions until the two are parts again unite at the starting gap between such electrode runner ends. As the two parts of the split arc are reunited the current is once more in such a direction that the magnetic field bends it into a curve with the central portion forced against the surface of the workpiece and the heating cycle is repeated. The above heating and are return cycles are continued until the workpiece has been heated as required to perform a desired glass working operation.
The workpiece may be heated in the above fashion with or without the benefit of heat by electric conduction. The preferred variation of the method is entirely dependent on the size, shape characteristic, or composition of the workpiece. Preferably, if the workpiece has a coating thereon in the region adjacent that to be worked which might be damaged by conduction heating, such form of heating is avoided by maintaining the applied potential below that at which the heated glass will accept an appreciable amount of current. Such method is also most appropriate when the composition of the workpiece is such that it is a poor conductor even at high temperatures, such for example as fused silica.
In the non-conduction form of heating, heating rates can be accelerated when arc trapping ledges can be formed, as at the junction of a seal when thick and thin section workpieces are to be joined to one another. Similarly, arc trapping grooves can be formed between two workpieces of substantially the same wall thickness if the meeting edge of at least one of such workpieces is bevelled back from its inner edge to provide an arc trapping groove along the line of juncture of the workpieces. Regulation of the heat input during arc flame heating can be effected by variation of the magnetic field strength.
When unusually high precision heat control is required, irrespective of whether flame or conduction heating is taking place, it can be achieved by accurately timed application of heating current interspersed with short periods of cooling. The rate of heating under these circumstances is determined by the current through the are multiplied by the voltage across it and its time-on to time-off ratio.
When conduction heating is employed a high enough potential is used to pass a susbtantial amount of current through the workpiece as soon as it has attained a conductive temperature. Therefore, in the late stages of glass workpiece heating by electric conduction, the discharge are is no longer stretched around the workpiece, but instead travels along the hot stripe in the glass just as it would travel along an arc-runner electrode. During this final stage of the process, the short arcs between the electrodes and the return conductor serve almost entirely as electrically conducting brushes conveying heating current into and out of the hot conducting glass. The magnetic field however in which heating is taking place at all times keeps the arcs in rapid motion over the arcrunner electrodes and thus insures that the heat concentration of the arc is never such as to destroy either the surfaces of the electrodes or of the workpiece. The electrodes also provide complete protection against heat loss by surface flashover in the event that the power supply exceeds the energy acceptance of the glass at any stage of the process.
When the length of the heating path is short, as in the treatment of miniature workpieces, two runner electrodes may suflice. When the paths are longer four or more electrodes are preferably employed. Under the latter circumstances the heat input may be effected by applying power to adjacent pairs of electrodes in succession, or alternatively when higher speed heating is desired; power may be concurrently applied to different groups of the electrodes to concurrently heat the respective sections of the workpiece along such path.
Moreover, if the workpiece is so positioned that the arcs travel along a horizontal path hollow electrodes may be employed, having open slots faced toward the workpiece and with such electrodes connected to a vacuum line, tocounteract the tendency for hot gases generated by the arc to rise by convection and thus aid the magnetic field in confining the are heat to a very narrow region.
Irrespective of the conduction heating method employed, the operation may, if desired, be further accelerated: to some. extent by application of a stripe of conductive material along the heating path. With such a. stripe present, electric conduction heating can be established. substantially immediately.
Als0,. irrespective of the heating method employed, uniform heating of a circular path about a circular workpiece: may be assured by its rotation or its oscillation about its axis as heating proceeds. It is, of. course, alsopossible to effect even heating by rotation or oscillation-of the electrodes about the workpiece, or to cause them to travel thereabout, but such practices usually introduce mechanical complexities that are preferably avoided. If the: path to be heated is noncircular, or if for one reason or another rotation of the workpiece isto be avoided, uniform heating can be assured by periodically reversing the direction of arc travel so that the starting gaps are repeatedly interchanged. Such reversals may be effected either by reversing the direction of the magnetic field, or by reversing the arc current relative to the magnetic current in any suitable or approved fashion, as by simple reversing switches under appropriate timer control.
Also, according to the invention, an arc travel and dwell type of operation is possible and may afford certain advantages under certain circumstances. Such an arrangement embodies a number of arc travel stopping gates in suitable positions along the arc runner electrodes that may be operated at will to stop the arc travel or be disabled to permit resumption of the arc travel. This type of operation can be obtained by association with the arc-runner electrodes .of movable conductors or gates which can be extended into closer promixity of the workpiece than are the runner electrodes to stop thearc, or be retracted to allow arc travel to be resumed, or by the use of vacuum electrodes such as disclosed in Patent No. 2,590,173 in lieu of such movable couductors. I
For a better understanding of the invention reference is made to the accompanying drawings in which:
Fig. 1 is a side elevation, partly in section of an apparatus suitable for practicing the invention and showing av tubular workpiece associated therewith.
Fig. 2 is a view taken on line 22 of Fig. 1.
vFig. 3 is a diagrammatic representation of the arrangement of Fig. l and of its operating circuit.
Fig. 4 diagrammatically illustrates an alternative form of the apparatus arranged about a workpiece which may be: of large diameter.
Fig.. 5 diagrammatically illustrates another form of the apparatus arranged about a workpiece and circuits for feeding power to its electrodes.
Fig. 6 diagrammatically illustrates the structural arrangement of Fig. 5, but with an alternative power feed system.
Fig. 7 diagrammatically illustrates a still further alternative arrangement and a power feed therefor.
Fig. 8- diagrammatically illustrates a structure employing hollow electrodes.
Fig. 8a is a sectional view taken on line 8a-8a of Fig. 8.
Fig. 9 diagrammatically illustrates the arrangement of electrodes as in Fig. 1, but with a power supply circuit especially suitable for low cost precision heat input control.
Fig. 10 diagrammatically illustrates an arrangement wherein the electrodes have associated therewith gates. for effecting an arc travel and dwell type of operation.
Figs. ll, 12 and 13 illustrate three different forms of power supply networks any which may be used with any, of the electrode arrangements shown.
Referring to Figs. 1 and 2 in detail, there is shown a base 11 provided with a vertical column 12, from a lower region of which a platform 13 projects and on which is mounted a hollow core magnet 15. A tube 17 of highly refractory dielectric material surrounds the magnet 15 and has an inwardly extended flange 18 that serves as a support for arc runner electrodes 19 and 20 and for an arc return conductor 21. The flange 18 also serves to protect the magnet 15 from arc flames that issue between the runner electrodes 19 and 20 and a workpiece such as 25. Workpiece 25 is suspended within the bore of magnet 15 from a chuck 26 attached to the lower end of a vertical shaft 27 supported from a side arm 28 projected from column 12. The upper end of shaft 27 is provided with a pulley 30 by means of which the shaft may be rotated if desired, although rotation of the workpiece is not necessary. A winged screw 31 is provided to lock the shaft 27 against rotation if desired.
With an arrangement such as shown in Figs. 1, 2 and 3, electric power is applied to the electrodes 19 and 20 at a voltage high enough to cause an arc discharge across the gap 22, the shorter of the two gaps 22 and 23 therebetween. As shown current from a 440 v. alternating current supply is fed through a saturable reactor SA and the primary winding of a transformer T whose secondary winding transmits the sealing current through a reversing switch RS1 to electrode 19 and through a second reversing switch. RS2 and the winding of magnet 15 in series, to the electrode 20. In the absence of a magnetic field the resulting arc would follow a straight line across gap 22. Such field, however, will bend the are into a curve that forces part of the arc stream against the surface of the workpiece 25 directly opposite gap 22. The bent arc will have thus acquired, by this action,.a shape such that the. arc current will be traveling in three different directions in the three different parts of the discharge path, as shown in- Fig. 2, by the interrupted line designated by the letters a, b and 0. At a, the current is moving from are runner electrode 19 toward the workpiece, at b, it is moving along the workpiece surface, and at c it is moving from the workpiece toward arc runner electrode 20. The field of magnet 15 however, has the same directionout of the plane of the diagram-at all of these points. Therefore, since the arc current must move at right angles to the field and to its own instantaneous direction, part a moves to the left and part 0 moves to the right along the arc runner electrodes 19 and 20 respectively, while part b is anchored to the surface of the workpiece 25, against which it is forced bythe field of magnet 15. Since both arc ends a and 0 continue to move rapidly in opposite directions over the arc runner electrodes 19 and 20 and the central arc column b remains blocked by the workpiece surface, the arc stretches and wraps itself tightly around the workpiece which is thereby heated in the zone of interception of the encircling arc column.
As the arc arrives at the electrode ends, it bows out ward toward the return conductor 21 as indicated by interrupted line d across the gap 23, and as it contacts return conductor 21 it splits up into parts e and. 1. which carry current in the opposite directions indicated, and continue such travel. until they again join one another at gap 22, whereupon the describedheating cycle is repeated.
The above described heating cycles, interspersed with arc return cycles, continue until an electrically conducting stripe is formed on the workpiece surface. Thereafter, by maintenance of a suitable current potential, electric conduction heating is established and continues until the workpiece 25 is suitably melted along the heat input line. I In the late stages of heating by electric conduction, the arc discharge is no longer stretched around the surface of the workpiece, but instead travels along the hot stripe in the workpiece just as it would travel over an arc-runner electrode. During this final period of the process, the short arcs, such as e and f, serve almost entirely as electrically conducting brushes conveying heating current into and out of the hot conducting glass. The magnetic field, however, still keeps the arcs in rapid motion over the arc runner electrodes 19 and 20 and insures against the are destroying of either the surface of the runner electrodes or the workpiece. 'Ihe electrodes also provide complete protection against heat loss by surface flashover in the event that the power supply exceeds the energy acceptance of the workpiece at any stage of the process, because the magnetic field continues to drive the arc column or plasma against the glass.
If the workpiece 25 is to be heated by the non-conduction method, as previously pointed out, the input potential is merely held below that at which any substantial amount of current will be caused to flow through the heated glass and the series ballast reactance is reduced to increase the arc current. The glass is then wholly heated by the current carried by the arc stretched thereabout, rather than by current flowing through it.
In the showing of Figs. 1 and 2, uniform heating may be assured by rotation of the workpiece or by periodically operating switch RS1 to periodically reverse the direction of current flow to the electrodes 19 and 20, or alternatively, by similarly operating switch RS2 to periodically reverse the polarity of magnet 15, to reverse the direction of arc travel.
In Fig. 1 the glassworking operation is illustrated as applied to the severance of the workpiece 25 along the interrupted line 32 and as is obvious the lower section of the workpiece will be dropped, upon severance, onto a support 27. As will be clearly evident, a workpiece arranged on support 27 can be elevated into engagement with a workpiece held in chuck 26, and by appropriate control of the applied potential the two workpieces can then be sealed together by either of the described glass- Working methods.
Although methods of glass working, utilizing but two arc-runner electrodes, as above described, are capable of satisfactorily working glassware of small dimensions, large workpieces can be more satisfactorily worked by using a greater number of arc-runner electrodes arranged along or around the workpiece, for example as illustrated in Fig. 4. In this illustration eight arc-runner electrodes such as 41 are shown arranged about a workpiece 40'. Suitably supported power supply brushes 42 and 43 are rotated about the electrodes to successively connect power to adjacent pairs thereof to successively heat segments of a path about the workpiece in the same fashion that the entire path about workpiece 25 is heated by power supplied to electrodes 19 and 20.
Alternatively, as illustrated in Fig. 5, the same results as with rotating brushes can be obtained by using distribution switches S1S8. This is accomplished by so exciting each of the arc-runner electrodes 51-54 in sequence that each is paired alternately with the one ahead of it and the one behind it to progressively scan the workpiece with a traveling arc. In the showing of Fig. 5 the distribution switches S1S8 are illustrated as being operated by their associated magnets in the desired pair combinations in succession by means of a suitable step-by-step distributor switch DS. As will be seen, in this arrange,- ment when the wiper W engages contact 1, circuits are closed for the magnets of switches S1 and S8 which operate and thus connect the power supply line conductors L1 and L2 to are runner electrodes 51 and 52 respectively. The operating circuits for the magnets of switches S1 and S8 extend from an X terminal of a suitable current source, through wiper W, conductor 55 and through the magnet of switch S1 to a Y terminal of the same current source, and via a branch conductor 56 through the magnet of switch S8 to a second Y terminal of such current source respectively. The circuit to electrode 51 extends from line L1, through conductor 57 and the contacts of switch S1. The circuit to electrode 52 extends from line L2 through conductor 58 and the contacts of switch S8. Similar circuits are established to connect the leads L1 and L2 to the adjoining pairs of arc runner electrodes 52 and 54, 54 and 53 and 53 and 51 respectively in succession as switch wiper W successively engages its contacts 2, 3 and 4.
In some instances, as when particularly large workpieces are to be worked, it may be desirable to simultaneously heat the different sections thereof along a path thereabout. By way of example, power can be separately supplied to the electrodes 51 and 52 and to 53 and 54 respectively which would eifect the simultaneous heating of the respective halves of the workpiece along a path thereabout in the same manner in which the workpiece 25 is heated by a single pair of electrodes.
A further alternative way of simultaneously heating the respective halves of a workpiece along a path thereabout is shown in Fig. 6 wherein arc- runner electrodes 61 and 63 are connected via suitable distributor impedances, in the present instance shown as capacitors C1 and C3 to conductor 66 of a heating current source and the remaining alternately disposed electrodes 62 and 64 are connected via suitable distributor capacitors C2 and C4 to the other conductor 67 of such source. With such an arrangement arc travel occurs concurrently between the adjacent ends of the respective paired electrodes; and as in the description of the two-electrode arrangement, the arcs travel to their opposite ends while being wrapped about the adjacent section of the workpiece 68. As in the showing of Figs. 2, 4 and 5, there is an arc return conductor, designated 65, which is contacted by the respective arcs which split up and return thereover to their starting points as in the preceding arrangements.
As illustrated in Fig. 7, another way of heating a large workpiece 70 is to surround it with alternately arranged active and passive runner electrodes, such as 71 through 78, and by connecting separate power sources to the electrodes 71 and 77 and to the electrodes 73 and 75' respectively. In this arrangement two active electrodes are to the passive electrodes and the two series connected arcs behave as in the preceding description since they circulate about their respective electrodes and return via the common arc return conductor 80.
The arrangement of Fig. 8 is equivalent to those in Figs. 5 and 6, but the electrodes 81 to 84 are hollow, as made clear in Fig. 8a, and each has a narrow slot such as 85 along its length open toward the workpiece 86. Such electrodes are surrounded by an arc return conductor 89. Vacuum lines such as 87 are in communication with the electrodes to establish the necessary suction along the electrode slots to neutralize any thermal updraft created by the arcs, when the electrodes are arranged in a horizontal plane, as in Fig. 1. As illustrated such electrodes are also provided with passages such as 89' through which an electrode cooling medium may be circulated, from a coolant line such as 88.
As illustrated in Fig. 9, again showing an electrode arrangement like that of Fig. 3, when high precision heat control is required the heating current may be economically supplied from a 440 v. 60 cycle power supply and arc currents to insure deflection of the arc in desired directions.
What is claimed is:
1. The method of electrically heating a hard glass body along a desired path, which comprises establishing an arc between the ends of electrodes spaced alongside such path, and creating a magnetic field about such path in which the magnetic lines of force are normal thereto to force the arc to travel along said electrodes in intimate contact with the glass to thereby heat it along such path.
2. A method such as defined by claim 1 which comprises concurrently creating a plurality of arcs between adjacent ends of electrodes spaced alongside such path under the influence of such magnetic lines of force to concurrently heat different sections of the glass along such path.
3. A method such as defined by claim 1 which comprises successively creating arcs between the diiferent ends of different electrodes spaced alongside such path under the influence of such magnetic lines of force to heat respective sections of the glass along such path in succession.
4. A method such as defined by claim 1 which comprises employing an electrical heating potential such that the voltage drop in the arc plasma is not sufficient to cause the arc current to transfer to the heated glass throughout the heating period.
5. A method such as defined by claim 1 which comprises employing an electric heating potential suificient to cause the arc current to fiow through the heated glass path when it attains a conductive temperature.
6. A method such as defined by claim 1 which includes starting and maintaining the arc by superimposing high frequency pilot waves on the electrodes for the heating periods.
7. A method such as defined by claim 1 which includes counteracting heat convection cu rents generated by are 10 heat to aid in restriction of the width of path in the glass heated by the arc.
8. A method such as defined by claim 1 which includes stopping the arc travel along selected regions of such path for a controlled period of time.
9. A method such as defined by claim 1 wherein the arc travel is continued throughout the total heating period.
10. A method such as defined by claim 1 wherein the travel of the arc is stopped in a position of optimum heating for a controlled period of time.
11. The method of working a hard glass body along an imaginary line thereon, which comprises creating from an alternating current supply source an electric arc alongside thereof and parallel to a segment of such line, creating an associated magnetic field having a component that passes at right angles to such line to cause such arc to progressively extend itself under the influence of such field about the glass body, and causing the arc to separate and return to its starting point after it has been stretched for a predetermined distance about the glass body.
12. A method such as defined by claim 11 wherein heating is accelerated by maintaining the arc in an arc trapping groove confined by the workpiece.
13. A method such as defined by claim 11 wherein power is supplied for predetermined time periods interspersed with time periods of air cooling of the workpiece by the surrounding atmosphere.
References Cited in the file of this patent UNITED STATES PATENTS 1,194,124 Barrow Aug. 8, 1918 2,046,117 Guest June 30, 1936 2,306,054 Guyer Dec. 22, 1942 2,428,969 Guyer Oct. 14, 1947 .7. 5 Lafldis st l- ':':1-.--.':.'.'-?':':' .q .949
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Cited By (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3011265A (en) * 1955-03-11 1961-12-05 Duplate Canada Ltd Dehydration of glass surfaces
US3369883A (en) * 1964-10-27 1968-02-20 Corning Glass Works Method of softening glass for punching holes therein by heating with a high frequency pulse current
US20050223748A1 (en) * 2004-03-30 2005-10-13 Ames Donald J Method of joining optical fiber preforms and apparatus therefor
US7694532B1 (en) * 2002-09-19 2010-04-13 Boaz Premakaran T System and method for tempering glass containers
US20130047673A1 (en) * 2011-08-31 2013-02-28 Samsung Corning Precision Materials Co., Ltd. Glass Tempering Method And Apparatus

Citations (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US1194124A (en) * 1916-08-08 Method of wobking glass
US2046117A (en) * 1934-06-22 1936-06-30 Gen Electric Arc welding apparatus
US2306054A (en) * 1938-02-19 1942-12-22 Corning Glass Works Glass heating and working
US2428969A (en) * 1943-10-11 1947-10-14 Corning Glass Works Glass heating and working
US2472851A (en) * 1944-09-23 1949-06-14 Lincoln Electric Co Apparatus for electromagnetically controlling welding arcs

Patent Citations (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US1194124A (en) * 1916-08-08 Method of wobking glass
US2046117A (en) * 1934-06-22 1936-06-30 Gen Electric Arc welding apparatus
US2306054A (en) * 1938-02-19 1942-12-22 Corning Glass Works Glass heating and working
US2428969A (en) * 1943-10-11 1947-10-14 Corning Glass Works Glass heating and working
US2472851A (en) * 1944-09-23 1949-06-14 Lincoln Electric Co Apparatus for electromagnetically controlling welding arcs

Cited By (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3011265A (en) * 1955-03-11 1961-12-05 Duplate Canada Ltd Dehydration of glass surfaces
US3369883A (en) * 1964-10-27 1968-02-20 Corning Glass Works Method of softening glass for punching holes therein by heating with a high frequency pulse current
US7694532B1 (en) * 2002-09-19 2010-04-13 Boaz Premakaran T System and method for tempering glass containers
US20100147028A1 (en) * 2002-09-19 2010-06-17 Boaz Premakaran T System and method for tempering glass containers
US20050223748A1 (en) * 2004-03-30 2005-10-13 Ames Donald J Method of joining optical fiber preforms and apparatus therefor
US20130047673A1 (en) * 2011-08-31 2013-02-28 Samsung Corning Precision Materials Co., Ltd. Glass Tempering Method And Apparatus

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