US2725199A - Automatic potentiometer winder - Google Patents

Automatic potentiometer winder Download PDF

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US2725199A
US2725199A US228738A US22873851A US2725199A US 2725199 A US2725199 A US 2725199A US 228738 A US228738 A US 228738A US 22873851 A US22873851 A US 22873851A US 2725199 A US2725199 A US 2725199A
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wire
potentiometer
resistance
mandrel
wound
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John L Bower
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North American Aviation Corp
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    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01CRESISTORS
    • H01C17/00Apparatus or processes specially adapted for manufacturing resistors
    • H01C17/04Apparatus or processes specially adapted for manufacturing resistors adapted for winding the resistive element
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01JELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
    • H01J19/00Details of vacuum tubes of the types covered by group H01J21/00
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01JELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
    • H01J2893/00Discharge tubes and lamps
    • H01J2893/0001Electrodes and electrode systems suitable for discharge tubes or lamps
    • H01J2893/0012Constructional arrangements
    • H01J2893/0026Machines for manufacture of grids or anodes

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  • FIG. 1 A first figure.
  • FIG. 1 is a schematic drawing of the invention.
  • Fig. 2 is a circuit diagram of the highinput impedance amplifier of this invention.
  • a carriage 1 supported on tracks 2 and 3 supports container 4 containing fluid bath 5 and supporting rollers 6, 7, and 8.
  • Jewel 9 is also supported on carriage 1 which is movable along tracks 2 and 3 by lead screw 10.
  • Lead screw 10 is rotated by motor 11 driven by servo amplifier 12.
  • slider arm 13 of master potentiometer 14 which is fixed and does not move with carriage 1.
  • Wire 15 wound on spool 16 passes through fluid bath 5, passing over rollers 6 and 7 and under roller 8.
  • the wire leads through jewel 9 and is wound .on mandrel 17 which is turned by motor 18.
  • Motor 18, motor 11, tracks 2 and 3, and master potentiometer 14 are supported upon base 34.
  • the D.-C. level control for high input impedance amplifier 19 is taken from the end of wire 15 on spool 16 through resistance 21'? with capacitor 21 connected as a low pass filter.
  • Wire 15, which is the resistance wire with which the potentiometer is wound, is connected at its end to slip ring 22 which is conductively connected to the lower end of master potentiometer 14 and to the input of inverting amplifier 23.
  • the output of amplifier 23 is connectedby resistance 24 to a junction with resistances 25 and 26 which are connected to slider 13 and ground, respectively.
  • the upper end of master potentiometer 14 is connected tothe output of amplifier 19 and by resistance 27 to the secondary, of transformer 28.
  • the secondary of transformer 28 is in turn connected to the end of wire 15 which is wound on spool 16.
  • Amplifier 19 is shown in detail in Fig. 2.
  • Container 4 is connected through a capacitor to the grid of.
  • the output of triode 29 is amplified in voltage amplifier 30 and applied to cathode follower 31.
  • the output of cathode follower 31 forms the input to voltage amplifier 32.
  • the output of voltage amplifier 32 forms the input of cathode follower 33 whose output is connected as shown in Fig. 1 to master potentiometer 14.
  • This apparatus may be used for winding a potentiometerupon mandrel 17, which may be of variable cross-sectional area and shape, in such a manner that the resistance at any point on the potentiometer bears any predetermined ratio to the resistance taken at a similar point on the master potentiometer.
  • a potentiometerupon mandrel 17 which may be of variable cross-sectional area and shape, in such a manner that the resistance at any point on the potentiometer bears any predetermined ratio to the resistance taken at a similar point on the master potentiometer.
  • tiometer 14 Wire 15 is attached to slip ring 22 and alternating current is applied to the primary of transformer 28. Likewise, current is applied to motor 18 which begins winding wire 15 on mandrel 17. As the resistance of the lower portion of master potentiometer 14 diflfers from the resistance of the wire wound upon mandrel 17, a signal appears at the junction of resistances 24, 25, and 26, is amplified in servo amplifier 12, and used to drive servo motor 11 to advance or retard carriage 1 by means of lead screw 10. Lead screw 10 is turned until the resistance of the wire wound on mandrel 17 is equal to the resistance of the master potentiometer between slider 13 and the lower end thereof.
  • Wire 5 may vary in cross-section enough to make a potentiometer of which it is wound nonlinear if no automatic control were employed. Therefore, the spacing of the turns of wire on mandrel 17 is varied to compensate for small variations in resistance of the wire due to variations in cross-section or variations in composition of the wire. From the figure, it may be seen that the resistances of the wire wound on mandrel 17, the resistance of the lower part of the master potentiometer, and resistances 24, 25, and 26 form a bridge,
  • the resistance of the master potentiometer and the wound potentiometer forming one arm of the bridge and resistances 25 and 26 forming the other arm of the bridge.
  • the potentiometer wound by this apparatus upon mandrel 17 Will likewise be nonlinear in the same relationship.
  • the potentiometer wound upon mandrel 17 may be made to bear any predetermined ratio to the master potentiometer, which ratio is determined by the relation of resistance 25 to resistance 24. Therefore, linear or nonlinear potentiometers proportional to any master potentiometer according to any predetermined ratio may be wound by this apparatus.
  • liquid bath 5 which may consist of water, is provided with conducting container 4 to form a capacitive connection with the wire at a point adjacent to where the wire is being wound upon mandrel 17.
  • the signal from this capacitive connection is fed to high input impedance amplifier 19 whose output signal is adjusted to supply a potential to the upper end of master potentiometer 14 such that wire 15 at the point where it is being wound upon mandrel 17 will be held at ground potential.
  • D.-C. level control is supplied from the end of wire 15 which is wound upon spool 16.
  • a low pass filter consisting of resistance 20 and capacitor 21 as shown in the figure, is used to supply this D.-C. level control.
  • the input to amplifier 19 is connected through a capacitor so that in case wire 15 is poorly insulated, the D.-C. potential of the wire does not affect the grid bias of the first stage of amplifier 19.
  • lead screw can be driven by motor 18 so that carriage 1 is advanced at a uniform rate, with mandrel 17 being driven by servo motor 11 and amplifier 12'.
  • Apparatus for winding a potentiometer with unbroken insulated resistance wire so as to be precisely proportional to a master potentiometer comprising a rotatable mandrel restrained against longitudinal movement, means for paying said insulated resistance wire onto said mandrel as it rotates, capacitive detector means associated with said paying means for sensing the potential of said insulating wire at the point where said wire is being wound on said mandrel without piercing the insulation of said wire, electronic servo means responsive to said capacitive detector means and connected to adjust the potential applied across said resistance wire in a manner to maintain said wire at the point where said wire is being wound on said mandrel at substantially ground potential, contact means associated with said paying means for sampling the resistance of said master potentiometer, means for advancing said paying and sampling means along said mandrel and said master potentiometer at a uniform rate, and means for varying the speed of rotation of said rotatable mandrel in response to the difference between the resistance of the wire wound on said mand
  • an automatic potentiometer winder of the type in which the spacing of the turns of insulated resistance wire wound on a mandrel is varied in response to the difference between the resistance of a master potentiometer and the resistance of the wire wound on said mandrel so as to maintain proportionality between the resistance at corresponding points on the potentiometer being wound and the master potentiometer, means for continuously sensing the resistance of the wire wound on said mandrel without breaking the insulation around said wire comprising capacitive means for sensing the departure from ground potential of said insulated resistance wire Where it is being wound on said mandrel, means for applying a constant alternating current to the wound end of said potentiometer being wound, and means for applying a signal to said wound end of said potentiometer being wound in response to said sensing means of a polarity and magnitude to maintain said resistance wire where it is being wound on said mandrel at substantially ground potential whereby the potential of said end is a function of the resistance of the wire wound on said mandrel.
  • An apparatus for accurately sensing the resistance of an insulated resistance wire between one end and a point along its length comprising capacitive detector means sensitive to the A.-C. potential of said insulated wire at said point without piercing the insulation of said wire, amplifier means responsive to said detector means connected to apply a signal to said resistance wire through the ends thereof of a phase and amplitude to maintain said point at A.-C.
  • a potentiometer having a terminal connected to a common point with said end of said insulated resistance wire, a slider contacting said potentiometer, bridge means comparing the resistance of said insulated wire between said end and said' point to the resistance of the portion of said potentiometer between said slider and said common point, and servo means for moving said slider in response to the unbalance of said bridge means to maintain said bridge means in balance whereby the resistance of said insulated wire between said end and said point is exactly proportional to the resistance of said potentiometer between said slider and said common point.
  • Apparatus for automatically Winding a potentiometer of insulated resistance wire without piercing the insulation of said wire. so as to be electrically similar to a master potentiometer comprising an elongated mandrel for carrying the wire of said potentiometer to be Wound, means for rotating said mandrel at a constant speed, a spool for storing said wire to be wound on said mandrel, a carriage adapted to move only in the direction of the longitudinal axis of said mandrel, guide means carried on said carriage for paying said wire on said mandrel as said carriage moves, a conductive fluid bath, means for conveying said insulated resistance wire through said fluid bath immediately prior to paying said wire on said mandrel, a source of electric signals, means connecting said resistance wire and said master potentiometer in series across said source of electric signals, a slider attached to said carriage for contacting said master potentiometer, said master potentiometer being fixed in space, means utilizing the capacitance between said bath and said wire in said
  • Apparatus for automatically winding an insulated resistance wire onto a potentiometer form without piercing the insulation of said wire so as to be electrically similar to a master potentiometer comprising means for holding said master potentiometer stationary in space, a rotatable mandrel for holding said potentiometer to be wound, support means for holding said mandrel stationary in space with its longitudinal axis parallel to the longitudinal axis of said master potentiometer, a motor for rotating said mandrel, a carriage movable in a direction parallel to the axes of said master potentiometer and said mandrel, means attached to said carriage for paying resistance wire onto said mandrel as it rotates, slider means attached to said carriage and contacting said master potentiometer, a conductive fluid bath, means conveying said resistance wire through said conductive fluid bath at a point just prior to winding on said mandrel, means utilizing the capacitance between said conductive fluid bath and said resistance wire in said bath for producing a signai
  • a potentiometer winder for winding insulated re sistance wire on a mandrel to correspond electrically to a master potentiometer without piercing the insulation of said wire
  • a conductive fluid bath means for conveying said resistance wire through said fluid bath at a point just prior to being wound on said mandrel
  • means utilizing the capacitance between said conductive fluid bath and the wire in said conductive fluid bath for determining the magnitude of the resistance of the wire wound on said mandrel
  • means for varying the spacing of the turns of insulated wire on said mandrel in response to said resistance determining means are examples of the resistance wire wound on said mandrel.
  • Apparatus for automatically winding a potentiometer with insulated resistance wire so as to be precisely proportional to a master potentiometer without piercing the insulation of said wire comprising a rotatable mandrel restrained against longitudinal movement, means for paying resistance wire onto said mandrel as it rotates, a conductive fluid bath, means for conveying said resistance wire through said conductive fluid bath at the point where said Wire is payed onto said mandrel, signal generating means, means connecting said resistance wire and said master potentiometer in series across said signal generating means, capacitive detector means utilizing the capacitance between said conductive fluid bath and said resistance wire in said conductive fluid bath for sensing the deviation of said resistance wire in said conductive fluid bath from a ground potential, electronic servo means sensitive to the output of said capacitive detector means and connected to adjust the potential applied across said series connection in a manner to maintain .said wire in said bath at substantially ground potential, slider means associated with said paying means for contacting said master potentiometer, signal
  • Apparatus for automatically winding insulated resistance wire on a potentiometer without piercing the insulation thereof in a manner to be the electrical analog of a master potentiometer comprising a mandel, means for winding said wire on said mandrel with controllable spacing, a conductive fluid bath, means for conveying said resistance wire through said conductive fluid bath immediately prior to Winding on said mandrel, capacitive detector means utilizing the capacitance between said conductive fluid bath and said resistance wire in said conductive fluid bath sensitive to the deviation of said wire in said bath from a ground potential, a slider on said master potentiometer, means for advancing said slider in synchronism with the motion of said winding means along the axis of said mandrel, a source of electric signals, means connecting said resistance wire and said master potentiometer in series across said source of electric signals, electronic servo means responsive to said capacitive detector means for maintaining said wire in said conductive fluid bath at ground potential, a pair of fixed resistors bearing a predetermined
  • Apparatus for automatically winding unbroken insulated resistance wire on a potentiometer to be the electrical analog of a master potentiometer comprising a cylindrical mandrel, means for winding said insulated wire on said mandrel with controllable spacing, a conductive fluid bath through which said wire passes, capacitive means associated with said bath for producing a signal indicative of departure of the wire from ground potential, a slider on said master potentiometer, amplifier means having its output connected to said slider for correcting the potential of said slider so that said insulated wire is at ground potential where it passes through said bath, means for advancing said slider in synchronism with the motion of said winding means along the axis of said mandrel, a pair of fixed resistances bearing a predetermined ratio inter se which is a function of the ratio it is desired to establish between said master potentiometer and said potentiometer being wound, one of said resistances being connected between the other said resistance and said slider, an inverting amplifier having its input connected to the junction between said wound potenti

Description

J. L. BOWER AUTOMATIC POTENTIOMETER WINDER Nov. 29, 1955 2 SheetsSheec 1 Filed May 28 1951 SERVO AMP.
AMP.
INVERTING AMP.
FIG.
INVENTOR.
JOHN L. BOWER Wm wk ATTORNEY Nov. 29, 1955 J. L. BOWER 2,725,199
AUTOMATIC POTENTIOMETER WINDER Filed May 28, 1951 2 Sheets-Sheet 2 GE NE-Z I2K n- NVV n c LEVEL CONTROL JOHN L. BOW ER BY wan/15 ATTORNEY United States Patent 1 2,725,199 AUTOMATIC POTENTIOMETER WINDER John L. Bower, Downey, Calif., assignor to North American Aviation, Inc. Application May 28, 1951, Serial No. 228,738 9 Claims. (Cl. 242-9) This invention relates to potentiometers, and particularly to apparatus for winding such potentiometers autcmatically with high resolution and high resistance per unit length.
Automatic potentiometer winders devised in the past have not been capable of winding insulated potentiometer wire in a manner which takes into account variations in resistance along the length of the wire. Further, potentiometers wound of bare wire by methods which did take such resistance variations into account have left much to be desired as to resolution and maximum resistance per unit length because of the space necessarily left between turns to provide the necessary insulation. It is therefore an object of this invention to provide apparatus for winding potentiometers automatically with insulated wire.
It is another object of this invention to provide apparatus for automatically winding potentiometers so that they have identical resistance versus displacement characteristics.
It is another object of this invention to provide an automatic potentiometer winder for winding potentiometers of high resolution.
It is another object of this invention to provide potentiometers of high resistance per unit length.
It is another object of this invention to provide an automatic potentiometer winder adapted to wind a nonlinear potentiometer which is the duplicate of any other nonlinear potentiometer.
It is another object of this invention to provide an automatic potentiometer winder adapted to wind a potentiometer which is nonlinear and whose resistance at any point is a predetermined function of the corresponding resistance of any linear or nonlinear potentiometer.
Other objects of invention will become apparent from the following description taken in connection with the accompanying drawings, in which Fig. 1 is a schematic drawing of the invention; and
Fig. 2 is a circuit diagram of the highinput impedance amplifier of this invention.
Referring to Fig. l, a carriage 1 supported on tracks 2 and 3 supports container 4 containing fluid bath 5 and supporting rollers 6, 7, and 8. Jewel 9 is also supported on carriage 1 which is movable along tracks 2 and 3 by lead screw 10. Lead screw 10 is rotated by motor 11 driven by servo amplifier 12. Also attached to carriage 1 is slider arm 13 of master potentiometer 14 which is fixed and does not move with carriage 1. Wire 15 wound on spool 16 passes through fluid bath 5, passing over rollers 6 and 7 and under roller 8. The wire leads through jewel 9 and is wound .on mandrel 17 which is turned by motor 18. Motor 18, motor 11, tracks 2 and 3, and master potentiometer 14 are supported upon base 34. The input of high input impedance amplifier 19, more fully shown in Fig. 2, is taken from container 4 which is of conducting material. The D.-C. level control for high input impedance amplifier 19 is taken from the end of wire 15 on spool 16 through resistance 21'? with capacitor 21 connected as a low pass filter. Wire 15, which is the resistance wire with which the potentiometer is wound, is connected at its end to slip ring 22 which is conductively connected to the lower end of master potentiometer 14 and to the input of inverting amplifier 23. The output of amplifier 23 is connectedby resistance 24 to a junction with resistances 25 and 26 which are connected to slider 13 and ground, respectively. The upper end of master potentiometer 14 is connected tothe output of amplifier 19 and by resistance 27 to the secondary, of transformer 28. The secondary of transformer 28 is in turn connected to the end of wire 15 which is wound on spool 16.
Amplifier 19 is shown in detail in Fig. 2. Container 4 is connected through a capacitor to the grid of. triode 29, which is a cathode follower. The output of triode 29 is amplified in voltage amplifier 30 and applied to cathode follower 31. The output of cathode follower 31 forms the input to voltage amplifier 32. The output of voltage amplifier 32 forms the input of cathode follower 33 whose output is connected as shown in Fig. 1 to master potentiometer 14.
This apparatus may be used for winding a potentiometerupon mandrel 17, which may be of variable cross-sectional area and shape, in such a manner that the resistance at any point on the potentiometer bears any predetermined ratio to the resistance taken at a similar point on the master potentiometer. For example, referring to Fig. 1, let it be required to wind upon mandrel 17 a potentiometer which at any point has a resistance proportional to the resistance at a similarly displaced point on master poten-.
tiometer 14. Wire 15 is attached to slip ring 22 and alternating current is applied to the primary of transformer 28. Likewise, current is applied to motor 18 which begins winding wire 15 on mandrel 17. As the resistance of the lower portion of master potentiometer 14 diflfers from the resistance of the wire wound upon mandrel 17, a signal appears at the junction of resistances 24, 25, and 26, is amplified in servo amplifier 12, and used to drive servo motor 11 to advance or retard carriage 1 by means of lead screw 10. Lead screw 10 is turned until the resistance of the wire wound on mandrel 17 is equal to the resistance of the master potentiometer between slider 13 and the lower end thereof. The function of slider 13, therefore, is to sample the resistance of master potentiometer 14 at each point to which the slider is moved. Wire 5 may vary in cross-section enough to make a potentiometer of which it is wound nonlinear if no automatic control were employed. Therefore, the spacing of the turns of wire on mandrel 17 is varied to compensate for small variations in resistance of the wire due to variations in cross-section or variations in composition of the wire. From the figure, it may be seen that the resistances of the wire wound on mandrel 17, the resistance of the lower part of the master potentiometer, and resistances 24, 25, and 26 form a bridge,
the resistance of the master potentiometer and the wound potentiometer forming one arm of the bridge and resistances 25 and 26 forming the other arm of the bridge.
ponent because the output of inverting amplifier 23 exactly balances the potential of the junction between resistance 25 and resistance 24. Thus, if the master potentiometer is nonlinear, the potentiometer wound by this apparatus upon mandrel 17 Will likewise be nonlinear in the same relationship. Furthermore, the potentiometer wound upon mandrel 17 may be made to bear any predetermined ratio to the master potentiometer, which ratio is determined by the relation of resistance 25 to resistance 24. Therefore, linear or nonlinear potentiometers proportional to any master potentiometer according to any predetermined ratio may be wound by this apparatus.
In order to assure that inverting amplifier 23 will maintain the junction point between resistances 24 and 25 at A.-C. ground it is necessary that wire 15 be held at Patented Nov. 29, 5
ground potential where it is wound upon mandrel 17. Since the wire being wound upon the potentiometer is, in general, insulated, direct contact with the wire at this point cannot be made. Therefore, liquid bath 5, which may consist of water, is provided with conducting container 4 to form a capacitive connection with the wire at a point adjacent to where the wire is being wound upon mandrel 17. The signal from this capacitive connection is fed to high input impedance amplifier 19 whose output signal is adjusted to supply a potential to the upper end of master potentiometer 14 such that wire 15 at the point where it is being wound upon mandrel 17 will be held at ground potential. Since it is desired that amplifier 19' operate near the center of its linear range and supply relatively high level signals from a very weak input from capacitive container 4, D.-C. level control is supplied from the end of wire 15 which is wound upon spool 16. A low pass filter, consisting of resistance 20 and capacitor 21 as shown in the figure, is used to supply this D.-C. level control. The input to amplifier 19 is connected through a capacitor so that in case wire 15 is poorly insulated, the D.-C. potential of the wire does not affect the grid bias of the first stage of amplifier 19.
Alternatively, lead screw can be driven by motor 18 so that carriage 1 is advanced at a uniform rate, with mandrel 17 being driven by servo motor 11 and amplifier 12'.
Although the invention has been described and illustrated in detail, it is to be clearly understood that the same is by way of illustration and example only and is not to be taken by way of limitation, the spirit and scope of this invention being limited only by the terms of the appended claims.
I claim:
1. Apparatus for winding a potentiometer with unbroken insulated resistance wire so as to be precisely proportional to a master potentiometer comprising a rotatable mandrel restrained against longitudinal movement, means for paying said insulated resistance wire onto said mandrel as it rotates, capacitive detector means associated with said paying means for sensing the potential of said insulating wire at the point where said wire is being wound on said mandrel without piercing the insulation of said wire, electronic servo means responsive to said capacitive detector means and connected to adjust the potential applied across said resistance wire in a manner to maintain said wire at the point where said wire is being wound on said mandrel at substantially ground potential, contact means associated with said paying means for sampling the resistance of said master potentiometer, means for advancing said paying and sampling means along said mandrel and said master potentiometer at a uniform rate, and means for varying the speed of rotation of said rotatable mandrel in response to the difference between the resistance of the wire wound on said mandrel and a predetermined function of the resistance detected by said sampling means on said master potentiometer to thereby wind a potentiometer precisely proportional to said master potentiometer.
2. In an automatic potentiometer winder of the type in which the spacing of the turns of insulated resistance wire wound on a mandrel is varied in response to the difference between the resistance of a master potentiometer and the resistance of the wire wound on said mandrel so as to maintain proportionality between the resistance at corresponding points on the potentiometer being wound and the master potentiometer, means for continuously sensing the resistance of the wire wound on said mandrel without breaking the insulation around said wire comprising capacitive means for sensing the departure from ground potential of said insulated resistance wire Where it is being wound on said mandrel, means for applying a constant alternating current to the wound end of said potentiometer being wound, and means for applying a signal to said wound end of said potentiometer being wound in response to said sensing means of a polarity and magnitude to maintain said resistance wire where it is being wound on said mandrel at substantially ground potential whereby the potential of said end is a function of the resistance of the wire wound on said mandrel.
3. An apparatus for accurately sensing the resistance of an insulated resistance wire between one end and a point along its length comprising capacitive detector means sensitive to the A.-C. potential of said insulated wire at said point without piercing the insulation of said wire, amplifier means responsive to said detector means connected to apply a signal to said resistance wire through the ends thereof of a phase and amplitude to maintain said point at A.-C. ground potential, a potentiometer having a terminal connected to a common point with said end of said insulated resistance wire, a slider contacting said potentiometer, bridge means comparing the resistance of said insulated wire between said end and said' point to the resistance of the portion of said potentiometer between said slider and said common point, and servo means for moving said slider in response to the unbalance of said bridge means to maintain said bridge means in balance whereby the resistance of said insulated wire between said end and said point is exactly proportional to the resistance of said potentiometer between said slider and said common point.
4. Apparatus for automatically Winding a potentiometer of insulated resistance wire without piercing the insulation of said wire. so as to be electrically similar to a master potentiometer comprising an elongated mandrel for carrying the wire of said potentiometer to be Wound, means for rotating said mandrel at a constant speed, a spool for storing said wire to be wound on said mandrel, a carriage adapted to move only in the direction of the longitudinal axis of said mandrel, guide means carried on said carriage for paying said wire on said mandrel as said carriage moves, a conductive fluid bath, means for conveying said insulated resistance wire through said fluid bath immediately prior to paying said wire on said mandrel, a source of electric signals, means connecting said resistance wire and said master potentiometer in series across said source of electric signals, a slider attached to said carriage for contacting said master potentiometer, said master potentiometer being fixed in space, means utilizing the capacitance between said bath and said wire in said bath for producing a signal indicative of the departure of said wire in said bath from ground potential, electronic servo means responsive to said signal producing means and having its output connected to said series circuit in a manner to maintain the potential of said wire in said bath at ground potential, means responsive to the signal across said wound potentiometer and to the signal across said master potentiometer for producing an output proportional to the deviation of said signals from a predetermined ratio, and servo means for moving said carriage in response to the-output of said signal deviation producing means whereby the resistance of the wire wound on said mandrel is maintained in a predetermined. ratio with the resistance of said master potentiometer where. said slider contacts it.
5. Apparatus for automatically winding an insulated resistance wire onto a potentiometer form without piercing the insulation of said wire so as to be electrically similar to a master potentiometer comprising means for holding said master potentiometer stationary in space, a rotatable mandrel for holding said potentiometer to be wound, support means for holding said mandrel stationary in space with its longitudinal axis parallel to the longitudinal axis of said master potentiometer, a motor for rotating said mandrel, a carriage movable in a direction parallel to the axes of said master potentiometer and said mandrel, means attached to said carriage for paying resistance wire onto said mandrel as it rotates, slider means attached to said carriage and contacting said master potentiometer, a conductive fluid bath, means conveying said resistance wire through said conductive fluid bath at a point just prior to winding on said mandrel, means utilizing the capacitance between said conductive fluid bath and said resistance wire in said bath for producing a signai indicative of the departure of said wire in said bath from a predetermined potential, a source of electric signals, means connecting said resistance wire and said master potentiometer in series across said source of signals, electronic servo means responsive to said signal producing means for maintaining said wire in said bath at said predetermined potential, means for comparing the potential across said resistance wire wound on said mandrel with the potential picked oif by said slider, and servo means responsive to said voltage comparison means for changing the axial spacing of said resistance wire being wound on said mandrel whereby the resistance of said wound potentiometer is in a predetermined ratio with the resistance of said master potentiometer.
6. In a potentiometer winder for winding insulated re sistance wire on a mandrel to correspond electrically to a master potentiometer without piercing the insulation of said wire, the combination of a conductive fluid bath, means for conveying said resistance wire through said fluid bath at a point just prior to being wound on said mandrel, means utilizing the capacitance between said conductive fluid bath and the wire in said conductive fluid bath for determining the magnitude of the resistance of the wire wound on said mandrel, and means for varying the spacing of the turns of insulated wire on said mandrel in response to said resistance determining means.
7. Apparatus for automatically winding a potentiometer with insulated resistance wire so as to be precisely proportional to a master potentiometer without piercing the insulation of said wire comprising a rotatable mandrel restrained against longitudinal movement, means for paying resistance wire onto said mandrel as it rotates, a conductive fluid bath, means for conveying said resistance wire through said conductive fluid bath at the point where said Wire is payed onto said mandrel, signal generating means, means connecting said resistance wire and said master potentiometer in series across said signal generating means, capacitive detector means utilizing the capacitance between said conductive fluid bath and said resistance wire in said conductive fluid bath for sensing the deviation of said resistance wire in said conductive fluid bath from a ground potential, electronic servo means sensitive to the output of said capacitive detector means and connected to adjust the potential applied across said series connection in a manner to maintain .said wire in said bath at substantially ground potential, slider means associated with said paying means for contacting said master potentiometer, signal comparison means responsive to the potential at the common terminal between resistance wire and said master potentiometer and to the potential picked off by said slider means for generating an output signal which is a predetermined function of the deviation of said potentials from a predetermined ratio, and means for advancing said paying and slider means in response to the output of said signal generating means to thereby wind a potentiometer precisely proportional to said master potentiometer.
8. Apparatus for automatically winding insulated resistance wire on a potentiometer without piercing the insulation thereof in a manner to be the electrical analog of a master potentiometer comprising a mandel, means for winding said wire on said mandrel with controllable spacing, a conductive fluid bath, means for conveying said resistance wire through said conductive fluid bath immediately prior to Winding on said mandrel, capacitive detector means utilizing the capacitance between said conductive fluid bath and said resistance wire in said conductive fluid bath sensitive to the deviation of said wire in said bath from a ground potential, a slider on said master potentiometer, means for advancing said slider in synchronism with the motion of said winding means along the axis of said mandrel, a source of electric signals, means connecting said resistance wire and said master potentiometer in series across said source of electric signals, electronic servo means responsive to said capacitive detector means for maintaining said wire in said conductive fluid bath at ground potential, a pair of fixed resistors bearing a predetermined ratio inter se which is a function of the ratio it is desired to establish between said master potentiometer and said potentiometer being wound, one of said resistors being connected between the other of said resistors and said slider, an inverting amplifier having its input connected to the junction between said wound potentiometer and said master potentiometer and its output connected to the other of said fixed resistors, and servo means with its input connected to the junction between said resistors and its output connected to drive said advancing means whereby if said junction is not at ground potential said slider is moved in a direction and of a magnitude to bring said junction to ground potential.
9. Apparatus for automatically winding unbroken insulated resistance wire on a potentiometer to be the electrical analog of a master potentiometer comprising a cylindrical mandrel, means for winding said insulated wire on said mandrel with controllable spacing, a conductive fluid bath through which said wire passes, capacitive means associated with said bath for producing a signal indicative of departure of the wire from ground potential, a slider on said master potentiometer, amplifier means having its output connected to said slider for correcting the potential of said slider so that said insulated wire is at ground potential where it passes through said bath, means for advancing said slider in synchronism with the motion of said winding means along the axis of said mandrel, a pair of fixed resistances bearing a predetermined ratio inter se which is a function of the ratio it is desired to establish between said master potentiometer and said potentiometer being wound, one of said resistances being connected between the other said resistance and said slider, an inverting amplifier having its input connected to the junction between said wound potentiometer and said master potentiometer and its output connected to the other of said resistances, means for supplying an alternating current signal to said master potentiometer and said wound potentiometer connected in series, and servo means responsive to the deviation of the junction between said fixed resistances from a ground potential for driving said advancing means whereby if the input to said inverting means is not equal to a predetermined ratio of the potential at said slider said slider is moved until the resistance of said wound potentiometer bears the same ratio to said master potentiometer as said resistance connected to said inverting amplifier bears to the sum of said fixed resistances, and the input to said inverting amplifier becomes exactly equal to a predetermined factor of the potential picked off by said slider.
References Cited in the file of this patent UNITED STATES PATENTS 464,125 Varley, Jr. Dec. 1, 1891 1,789,451 Rosaire et al Jan. 20, 1931 1,820,647 Brown Aug. 25, 1931 2,401,954 Newton June 11, 1946 2,460,107 Slade June 25, 1949 2,500,605 De Lange et al Mar. 14, 1950 2,522,151 Weeks, Jr Sept. 12, 1950 2,568,465 Scott Sept. 18, 1951 2,639,864 Hale May 26, 1953 2,643,068 Harris, Jr June 23, 1953 2,668,670 Van Alen Feb. 9, 1954 FOREIGN PATENTS 494,777 Switzerland Nov. 1, 1938 120,713 Australia Dec. 10, 1945 606,430 Great Britain Aug. 13, 1948
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Cited By (8)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2893651A (en) * 1955-04-27 1959-07-07 Admiral Corp Method and apparatus for making antennas with ferrite cores
US2964252A (en) * 1957-01-24 1960-12-13 Gen Dynamics Corp Control system
US3022019A (en) * 1959-11-27 1962-02-20 Philco Corp Fabrication of electrical circuit components
US3203633A (en) * 1963-02-13 1965-08-31 Litton Industries Inc Precision winding machines and apparatus
US3302897A (en) * 1962-02-26 1967-02-07 Western Electric Co Machine for single-step winding and calibration of electrical articles
US4352465A (en) * 1979-01-08 1982-10-05 Grechanliisky Stepan S Device for manufacturing resistors from insulated wire
US4372497A (en) * 1979-01-08 1983-02-08 Dimitraki Sergei N Method of manufacturing wound items from coaxial microwire and device therefor
US11559681B2 (en) * 2016-12-16 2023-01-24 Medtronic, Inc. Modular lead

Citations (13)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US464125A (en) * 1891-12-01 Method of testing insulated wires
US1789451A (en) * 1926-06-05 1931-01-20 Western Electric Co Method of and apparatus for manufacturing electrostatic condensers
US1820647A (en) * 1929-08-13 1931-08-25 Brown Arthur Whitten Method of and means for indicating direction
US2401954A (en) * 1943-02-06 1946-06-11 Western Electric Co Testing apparatus
GB606430A (en) * 1944-06-09 1948-08-13 Sperry Gyroscope Co Inc Improvements in or relating to apparatus for the manufacture of potentiometers and rheostats
US2460107A (en) * 1945-12-29 1949-01-25 Okonite Co Apparatus for testing insulated wire and cable
US2500605A (en) * 1945-08-04 1950-03-14 Hartford Nat Bank & Trust Co Method and device for manufacturing electric resistance bodies
US2522151A (en) * 1948-03-13 1950-09-12 Bell Telephone Labor Inc Circuit for testing the dielectric strength of insulating material and recording puncture points
US2568465A (en) * 1949-01-03 1951-09-18 Gen Electric Electrical contact device
US2639864A (en) * 1943-12-20 1953-05-26 Fairchild Camera Instr Co Method of and apparatus for winding precision resistors
US2643068A (en) * 1944-06-09 1953-06-23 Sperry Corp Potentiometer winder
US2668670A (en) * 1947-12-15 1954-02-09 Borg George W Corp Coil winding machine
CH494777A (en) * 1964-07-31 1970-08-15 Bloechl Walter Polyfluoroalkyl derivatives of phosphorus acids

Patent Citations (13)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US464125A (en) * 1891-12-01 Method of testing insulated wires
US1789451A (en) * 1926-06-05 1931-01-20 Western Electric Co Method of and apparatus for manufacturing electrostatic condensers
US1820647A (en) * 1929-08-13 1931-08-25 Brown Arthur Whitten Method of and means for indicating direction
US2401954A (en) * 1943-02-06 1946-06-11 Western Electric Co Testing apparatus
US2639864A (en) * 1943-12-20 1953-05-26 Fairchild Camera Instr Co Method of and apparatus for winding precision resistors
GB606430A (en) * 1944-06-09 1948-08-13 Sperry Gyroscope Co Inc Improvements in or relating to apparatus for the manufacture of potentiometers and rheostats
US2643068A (en) * 1944-06-09 1953-06-23 Sperry Corp Potentiometer winder
US2500605A (en) * 1945-08-04 1950-03-14 Hartford Nat Bank & Trust Co Method and device for manufacturing electric resistance bodies
US2460107A (en) * 1945-12-29 1949-01-25 Okonite Co Apparatus for testing insulated wire and cable
US2668670A (en) * 1947-12-15 1954-02-09 Borg George W Corp Coil winding machine
US2522151A (en) * 1948-03-13 1950-09-12 Bell Telephone Labor Inc Circuit for testing the dielectric strength of insulating material and recording puncture points
US2568465A (en) * 1949-01-03 1951-09-18 Gen Electric Electrical contact device
CH494777A (en) * 1964-07-31 1970-08-15 Bloechl Walter Polyfluoroalkyl derivatives of phosphorus acids

Cited By (8)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2893651A (en) * 1955-04-27 1959-07-07 Admiral Corp Method and apparatus for making antennas with ferrite cores
US2964252A (en) * 1957-01-24 1960-12-13 Gen Dynamics Corp Control system
US3022019A (en) * 1959-11-27 1962-02-20 Philco Corp Fabrication of electrical circuit components
US3302897A (en) * 1962-02-26 1967-02-07 Western Electric Co Machine for single-step winding and calibration of electrical articles
US3203633A (en) * 1963-02-13 1965-08-31 Litton Industries Inc Precision winding machines and apparatus
US4352465A (en) * 1979-01-08 1982-10-05 Grechanliisky Stepan S Device for manufacturing resistors from insulated wire
US4372497A (en) * 1979-01-08 1983-02-08 Dimitraki Sergei N Method of manufacturing wound items from coaxial microwire and device therefor
US11559681B2 (en) * 2016-12-16 2023-01-24 Medtronic, Inc. Modular lead

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