US2434492A - Electric coil - Google Patents

Electric coil Download PDF

Info

Publication number
US2434492A
US2434492A US611788A US61178845A US2434492A US 2434492 A US2434492 A US 2434492A US 611788 A US611788 A US 611788A US 61178845 A US61178845 A US 61178845A US 2434492 A US2434492 A US 2434492A
Authority
US
United States
Prior art keywords
coil
winding
coil form
conducting
wire
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Expired - Lifetime
Application number
US611788A
Inventor
Alvah O Ericksberg
Joseph T Osterman
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Ambac International Corp
Original Assignee
American Bosch Arma Corp
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Priority claimed from US557710A external-priority patent/US2434511A/en
Application filed by American Bosch Arma Corp filed Critical American Bosch Arma Corp
Priority to US611788A priority Critical patent/US2434492A/en
Application granted granted Critical
Publication of US2434492A publication Critical patent/US2434492A/en
Anticipated expiration legal-status Critical
Expired - Lifetime legal-status Critical Current

Links

Images

Classifications

    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01FMAGNETS; INDUCTANCES; TRANSFORMERS; SELECTION OF MATERIALS FOR THEIR MAGNETIC PROPERTIES
    • H01F41/00Apparatus or processes specially adapted for manufacturing or assembling magnets, inductances or transformers; Apparatus or processes specially adapted for manufacturing materials characterised by their magnetic properties
    • H01F41/02Apparatus or processes specially adapted for manufacturing or assembling magnets, inductances or transformers; Apparatus or processes specially adapted for manufacturing materials characterised by their magnetic properties for manufacturing cores, coils, or magnets
    • H01F41/04Apparatus or processes specially adapted for manufacturing or assembling magnets, inductances or transformers; Apparatus or processes specially adapted for manufacturing materials characterised by their magnetic properties for manufacturing cores, coils, or magnets for manufacturing coils
    • H01F41/12Insulating of windings
    • H01F41/125Other insulating structures; Insulating between coil and core, between different winding sections, around the coil

Definitions

  • the present invention relates to electric coils and methods of making electric cells on heatresistant coil forms with wire terminals rigidly fastening the coil winding to the form, by bonding the end turns 01 the winding to separated conducting areas baked on the form.
  • Such coils employ relatively fine wire and are used generally as for instance in spark plugs in ignition systems of the capacitor discharge type, electrical instruments, and radio and other high frequency devices.
  • the foregoing difficulties are obviated by bonding the bare end turns of the coil winding to the conducting areas on the coil form by baking adherent metallic material spread over at least a substantial part of the contacting surfaces of the winding while the end turns thereof are held against the conduct-' ing areas.
  • insulated wire is used preferably, and to withstand the baking and operating temperatures this insulation is of the heat-resistant type.
  • the bonding operation, and also the operation of baking the conducting areas on the coil form are accomplished by gradually heating the coil form to the necessary temperature and thereafter gradually cooling it to room temperature, thereby avoiding 2 the subjection of the coil form to heat shocks and to excessive stresses and strains.
  • the conducting areas on the coil form constitute end bands of such width as will be covered by a number of turns of bare wire of the size used. so as to secure rigid terminals of uniform and permanent electrical character.
  • the same metallic material is used for producing the conducting areas on the form and for bonding the winding to those areas, since such subsequent bonding may then be accomplished at a temperature lower than is required to produce the conducting areas with the metallic material then penetrating the coil form. After the Winding is bonded to the conducting areas to form the coil terminals, it is preferable to adherently coat the terminals with highly conducting material to thereby increase the electric conductivity thereof.
  • the coil form is preferably cylindrical so as to take advantage of the reduced cost of cutting the forms into lengths from a long tube.
  • the form may have an integral cross Wall to which the spring is riveted.
  • the outer face of the cross wall is likewise coated with adherent metallic material at the time the conducting areas are formed on the outer surface of the form, and the cross Wallis likewise coated with the highly conductive material, to thereby produce a good electrical connection between the end of the coil winding and the spring.
  • one object of the invention is to provide electric coils and methods of producing electric coils having rigid term nals which are smooth and of substantially uniform dimensions and of uniform and permanent electrical characteristics.
  • Fig. 1 shows a cylindrical coil form
  • Fig. 2 shows the coil form of Fig. 1 after conducting bands of adherent metallic material are baked on each of its ends
  • Fig. 3 shows the coil form of Fig. 2 after there is wound thereon a coil of of the windin wire having an appropriate number of its turns at each end bared for bonding to the conducting bands
  • Fig. 4 shows the coil of Fig. 3 after its completion, the end turns of the winding being connected to the conducting bands by means of adherent metallic material appropriately baked to mechanically and electrically secure the winding to the conducting bands to form rigid terminals therewith, and the terminals being covered with a layer of copper applied thereto by electrolytic deposition or spraying
  • Fig. 5 is an enlarged detail of a completed terminal of Fig. 4
  • Fig. 6 shows a modified form of coil of this type provided with a spring terminal.
  • the tubular coil form I consists preferably of suitable ceramic material as porcelain, such as that used in sparkplug insulators.
  • the forms are cut from long tubes while plastic before firing, the corners at 2 of each form being rounded off by tuming or grinding.
  • bon tetrachloride to remove oil, grease and other foreign material therefrom each of its ends is coated by stenciling or in any other suitable way, with a band of commercial metallic paint consisting of 90% silver and 10% platinum.
  • Each band is of sufiicient width to underlie about 10-15 turns of wire subsequently wound on the coil form almost from end to end thereof.
  • bands are then baked on the coil form by gradually raising its temperature in a furnace to a value between 1000" F. and 1100" F. during a period of about 3 to 5 minutes. Then the coil form is gradually cooled to room temperature.
  • the coil form is not subjected to such heat shock, either while the temperature is being increased or decreased, as might crack or break it or might produce such stresses and strains therein as would cause its fracture upon ordinary mechanical shocks or vibration, and the paint is baked into the exterior pores of the ceramic and completely around the coil form, and if desired around its end surfaces also, in sharply defined bands 3 of continuously conducting metal of substantially uniform width and thickness.
  • the metallic band may be in the form of a paste and may contain pure silver or pure platinum or pure gold or other suitable adherent metallic materials including admixtures thereof such that after the baking operation there is no formation of metal oxide having a relatively high electrical resistance.
  • the wire is covered with an insulation which is a ceramic (inorganic) insulating coating on copper, nickel and other types of wire and which may contain resin and which is a heat-resistant capable of withstanding without change a temperature or at least 600 F.
  • Other insulation materials having suitable heat resisting characteristics may be used if desired.
  • This temperature of about 500 F. instead of the baking temperature of between 1000 F. and 1100 F. for the bands 3, suffices for the bonding operation between the end turns 5 and bands 3 because the first coating of paint requires a higher temperature for penetration of the ceramic while the second coating of paint does not require such penetration but merely a bond between two contact surfaces.
  • a second and heavier coating 6 of the same paint may preferably be baked over the bonded end turns at a gradually rising temperature finally reaching about 500 F. after a period of 2 to 2 hours.
  • This additional coating assists in producing a terminal I in which the end turns are rigidly secured to the band in a bond of comparatively low electrical resistance capable of withstanding a temperature in service of at least 600 F.
  • the terminals may then, if desired, be further covered by electrolytically plating them with copper, silver or other highly conducting metal 8 which does not melt at the temperature to which the coil is subjected in service, or by spraying them with suitable metal, to thereby further reduce the electrical resistance of the terminals.
  • each of the terminals 1 so produced is smooth all around its outer surface and o! uniform dimensions, comprising a substantially continuous bond between 10-15 shortcircuited end turns of the winding.
  • terminals and windings made in quantity have substantially uniform electrical resistance and result in coils of substantially uniform distributed inductants and capacity.
  • the terminals are mechanically rigid and not only are non-corroded when completed but do not corrode thereafter in such wise as would materially change the electrical resistance thereof.
  • the coil form is not so apt to be cracked or broken under stresses and strains such as may result in fracture under ordinary mechanical shock or vibration in handling or service.
  • Fig. form 9 has near one end an integral cross wall 10 which is perforated at I I, whereas the remainder of the coil form is tubular as before.
  • the bond between the bared end turns of the winding and the end bands or conducting areas are formed as before, but the initial coating of adherent metallic material is extended over the inner surface at l2 of the coil form and also over the outer surface of the cross wall III, to form a continuous conducting area at that end of the coil form.
  • the spring [3 is electrically fastened to the coil form, preferably after the winding is secured in place, with its ends connected to the conducting 6, the coil v area on the cross wall by a brass rivet l4.
  • Such a coil with a spring electrically connected to one terminal thereof, is useful in mounting in devices, such as spark plugs, having mounting dimensions which are variable within the compensation affol'ded by the spring l3.
  • this electric coil has the mechanical and electrical characteristics of the embodiment of Figs. 1-5.
  • the wire of the coil may be bare instead of insulated, the turns then being maintained in spaced relation in the well known way as by forming in the coil form a helical groove in which the wire is wound.
  • An electric coil comprising a heat-resistant, inorganic coil form, spaced conducting areas on said coil form, said. conducting areas comprising an adherent metallic material, a winding of wire surrounding the coil form, said winding having bare end portions secured to said conducting areas and a coating of an adherent metallic material over said bare end portions to thereby form bonded terminals for said coil.
  • An electric coil comprising a heat-resistant, inorganic coil form, spaced portions of said coil form having areas coated with a platinum-silver paint to form conducting areas, a winding of wire surrounding said coil form and extending over the conducting areas and the portion therebetween with bare end turns of the winding overlying at least a portion of said conducting areas and a coating of platinum-silver paint over said bare end turns of the winding to thereby rigidly fasten the coil to the coil form.
  • An electric coil comprising a heat-resistant, inorganic coil form, spaced portions of said coil form having areas coated with a highly conductive material to form conducting areas, a wire winding surrounding said coil form and extending over the conducting areas and the portion therebetween with bare end turns of the winding overlying at least a portion ofsaid conducting areas and a coating of highly conductive material over said bare end turns of the winding to thereby rigidly fasten the coil to the coil form.
  • An electric coil comprising a heat-resistant, inorganic coil form, spaced portions of said coil form having areas coated with a highly conductive material to form conducting areas, a winding on said coil form over the conducting areas and the portion therebetween with bare end turns of the winding overlying at least a portion of said conducting areas and a coating of highly conductive material over said bare end turns of the winding to thereby rigidly fasten the coil to the coil form, and a resilient terminal secured to said coil form and in contact with the conducting area thereon.

Landscapes

  • Engineering & Computer Science (AREA)
  • Power Engineering (AREA)
  • Manufacturing & Machinery (AREA)
  • Wire Processing (AREA)

Description

13, 1948. A. o. ERICJKSBERG in" AL. 2,434,492
ELECTRIC COIL Original Filed Oct. '7, 1944 INVENTORS. JOSEPH T. OSTE'EPIAN ALVAH O. ERICKSBEJEG I BY 4 AT Of/VEY' Patented Jan. 13, 1948 ELECTRIC COIL Alvah 0. Ericksberg, Springfield, and Joseph T. Osterman, Northampton, Mass., assignors to American Bosch Corporation, Springfield, Mass., a corporation of New York Original application October '7, 1944, Serial No. 557,710. Divided and this application August 21, 1945, Serial No. 611,788
4 Claims. 1
The present invention relates to electric coils and methods of making electric cells on heatresistant coil forms with wire terminals rigidly fastening the coil winding to the form, by bonding the end turns 01 the winding to separated conducting areas baked on the form. Such coils employ relatively fine wire and are used generally as for instance in spark plugs in ignition systems of the capacitor discharge type, electrical instruments, and radio and other high frequency devices. This application is a division of our application, Serial No. 557,710, filed October '7, i944.
Heretofore it was customary to solder the ends of the coil winding to conducting areas or bands sometimes baked on coil forms to produce the coil terminals, but this subjected the form to heat shocks of such nature as often fractured it particularly if silver solder was used, or set up such stresses and strains as resulted in unduly fragile forms which broke upon ordinary mechanical shock or vibration. Also, the electric contact between the wire and the conducting areas occurred at spots only, and the surface of the wire at the joints often corroded in'soldering and sometimes further thereafter so as to be faulty and nonuniform in resistance .upon completion besides deteriorating during service. Also the solder sometimes formed lumps and otherwise lacked uniformity in dimensions. which detracted from the smooth and regular dimensions of the terminal in such wise as to prevent reliable contact therewith in electrical devices and circuits. Furthermore, in application to spark plugs in which the coils were impregnated in place at comparatively high temperature and alsoin service reached a comparatively high temperature at the location of the coil, the solder would sometimes melt and thereupon interrupt the electrical circuit at one or both terminals of the coil.
In accordance with our'invention, the foregoing difficulties are obviated by bonding the bare end turns of the coil winding to the conducting areas on the coil form by baking adherent metallic material spread over at least a substantial part of the contacting surfaces of the winding while the end turns thereof are held against the conduct-' ing areas. In order to wind closely, insulated wire is used preferably, and to withstand the baking and operating temperatures this insulation is of the heat-resistant type. Preferably the bonding operation, and also the operation of baking the conducting areas on the coil form, are accomplished by gradually heating the coil form to the necessary temperature and thereafter gradually cooling it to room temperature, thereby avoiding 2 the subjection of the coil form to heat shocks and to excessive stresses and strains. Preferably also the conducting areas on the coil form constitute end bands of such width as will be covered by a number of turns of bare wire of the size used. so as to secure rigid terminals of uniform and permanent electrical character. Preferably also the same metallic material is used for producing the conducting areas on the form and for bonding the winding to those areas, since such subsequent bonding may then be accomplished at a temperature lower than is required to produce the conducting areas with the metallic material then penetrating the coil form. After the Winding is bonded to the conducting areas to form the coil terminals, it is preferable to adherently coat the terminals with highly conducting material to thereby increase the electric conductivity thereof.
In such coils, the coil form is preferably cylindrical so as to take advantage of the reduced cost of cutting the forms into lengths from a long tube. However, in case a spring terminal is required at one end of the coil to compensate for changes in dimensions in the device incorporating the coil, the form may have an integral cross Wall to which the spring is riveted. In this latter case the outer face of the cross wall is likewise coated with adherent metallic material at the time the conducting areas are formed on the outer surface of the form, and the cross Wallis likewise coated with the highly conductive material, to thereby produce a good electrical connection between the end of the coil winding and the spring.
Accordingly, one object of the invention is to provide electric coils and methods of producing electric coils having rigid term nals which are smooth and of substantially uniform dimensions and of uniform and permanent electrical characteristics.
Another object is to provide such methods as are applicable to the rapid and uniform production in quantity of inexpensive coils of this kind. These and other objects and advantages of the invention will be understood from the following description of two embodiments herein, using as examples ceramic coil forms and insulated wire, taken in conjunction with the accompanying drawings of which each is a central longitudinal section partly broken away near its middle portion. In the drawings:
Fig. 1 shows a cylindrical coil form; Fig. 2 shows the coil form of Fig. 1 after conducting bands of adherent metallic material are baked on each of its ends; Fig. 3 shows the coil form of Fig. 2 after there is wound thereon a coil of of the windin wire having an appropriate number of its turns at each end bared for bonding to the conducting bands; Fig. 4 shows the coil of Fig. 3 after its completion, the end turns of the winding being connected to the conducting bands by means of adherent metallic material appropriately baked to mechanically and electrically secure the winding to the conducting bands to form rigid terminals therewith, and the terminals being covered with a layer of copper applied thereto by electrolytic deposition or spraying;- Fig. 5 is an enlarged detail of a completed terminal of Fig. 4; and Fig. 6 shows a modified form of coil of this type provided with a spring terminal.
Referring to the embodiment of Figs. 1-5, the tubular coil form I consists preferably of suitable ceramic material as porcelain, such as that used in sparkplug insulators. Preferably, in order to reduce their cost, the forms are cut from long tubes while plastic before firing, the corners at 2 of each form being rounded off by tuming or grinding. After the fired coil form, as shown in Fig. 1, bon tetrachloride to remove oil, grease and other foreign material therefrom, each of its ends is coated by stenciling or in any other suitable way, with a band of commercial metallic paint consisting of 90% silver and 10% platinum. Each band is of sufiicient width to underlie about 10-15 turns of wire subsequently wound on the coil form almost from end to end thereof. These bands are then baked on the coil form by gradually raising its temperature in a furnace to a value between 1000" F. and 1100" F. during a period of about 3 to 5 minutes. Then the coil form is gradually cooled to room temperature. Thus in these steps of processing, the coil form is not subjected to such heat shock, either while the temperature is being increased or decreased, as might crack or break it or might produce such stresses and strains therein as would cause its fracture upon ordinary mechanical shocks or vibration, and the paint is baked into the exterior pores of the ceramic and completely around the coil form, and if desired around its end surfaces also, in sharply defined bands 3 of continuously conducting metal of substantially uniform width and thickness.
Instead of using porcelain, other heat-resistant coil forms, as steatite or glass-bonded mica may be used. Furthermore, the metallic band may be in the form of a paste and may contain pure silver or pure platinum or pure gold or other suitable adherent metallic materials including admixtures thereof such that after the baking operation there is no formation of metal oxide having a relatively high electrical resistance.
Having the finished coil form with conducting end bands thereon, as shown in Fig. 2, relatively small copper wire E of a B and S gage between No. 30 and No. 42 having a bare diameter of about 10 mils down to about 2.5 mils, is wound thereon substantially from end to end of the coil form as shown in Fig. 3. Preferably the wire is covered with an insulation which is a ceramic (inorganic) insulating coating on copper, nickel and other types of wire and which may contain resin and which is a heat-resistant capable of withstanding without change a temperature or at least 600 F. Other insulation materials having suitable heat resisting characteristics may be used if desired. About 10 to turns at each end 4 depending upon the size of wire making up about the width of the bands 3, are bared of its insulation in any suitable way as by is thoroughly cleansed with carscraping. The bare end turns 5 are then given a coating of paint, preferably of the same composition as the adherent metallic material of the end bands 3. While these coated turns are held down tightly against the bands 3 by spring clips or tape, and the winding 4 on that portion of the coil form therebetween maintained tight, the wire-wound coil form is bakedin a furnace at a gradually increasing temperature up to about 500 F. during a period of 3 to 5 minutes, and then gradually cooled, to bond the end turns 5 of the winding to the bands 3. The spring clips or tapes are then removed. This temperature of about 500 F., instead of the baking temperature of between 1000 F. and 1100 F. for the bands 3, suffices for the bonding operation between the end turns 5 and bands 3 because the first coating of paint requires a higher temperature for penetration of the ceramic while the second coating of paint does not require such penetration but merely a bond between two contact surfaces. Either before or after the wound coil form has its temperature from the second baking operation gradually reduced to the room temperature, a second and heavier coating 6 of the same paint may preferably be baked over the bonded end turns at a gradually rising temperature finally reaching about 500 F. after a period of 2 to 2 hours. This additional coating assists in producing a terminal I in which the end turns are rigidly secured to the band in a bond of comparatively low electrical resistance capable of withstanding a temperature in service of at least 600 F. Whether or not the additional coating is applied, the terminals may then, if desired, be further covered by electrolytically plating them with copper, silver or other highly conducting metal 8 which does not melt at the temperature to which the coil is subjected in service, or by spraying them with suitable metal, to thereby further reduce the electrical resistance of the terminals. Whether or not the step of electrolytical deposition or spraying is used, each of the terminals 1 so produced is smooth all around its outer surface and o! uniform dimensions, comprising a substantially continuous bond between 10-15 shortcircuited end turns of the winding. Also, such terminals and windings made in quantity have substantially uniform electrical resistance and result in coils of substantially uniform distributed inductants and capacity. Also the terminals are mechanically rigid and not only are non-corroded when completed but do not corrode thereafter in such wise as would materially change the electrical resistance thereof. Furthermore, due to the gradual application of heat and gradual reduction in temperature. the coil form is not so apt to be cracked or broken under stresses and strains such as may result in fracture under ordinary mechanical shock or vibration in handling or service.
In the modification shown in Fig. form 9 has near one end an integral cross wall 10 which is perforated at I I, whereas the remainder of the coil form is tubular as before. The bond between the bared end turns of the winding and the end bands or conducting areas are formed as before, but the initial coating of adherent metallic material is extended over the inner surface at l2 of the coil form and also over the outer surface of the cross wall III, to form a continuous conducting area at that end of the coil form. The spring [3 is electrically fastened to the coil form, preferably after the winding is secured in place, with its ends connected to the conducting 6, the coil v area on the cross wall by a brass rivet l4. Such a coil, with a spring electrically connected to one terminal thereof, is useful in mounting in devices, such as spark plugs, having mounting dimensions which are variable within the compensation affol'ded by the spring l3. Obviously, this electric coil has the mechanical and electrical characteristics of the embodiment of Figs. 1-5.
It will be apparent that in either of the embodimentsof Figs. l-5 or Fig. 6, the wire of the coil may be bare instead of insulated, the turns then being maintained in spaced relation in the well known way as by forming in the coil form a helical groove in which the wire is wound. This and other changes and modifications may be made without departing from the spirit of the invention as embodied within the broad terms of the appended claims.
Having described our invention, we claim:
1. An electric coil comprising a heat-resistant, inorganic coil form, spaced conducting areas on said coil form, said. conducting areas comprising an adherent metallic material, a winding of wire surrounding the coil form, said winding having bare end portions secured to said conducting areas and a coating of an adherent metallic material over said bare end portions to thereby form bonded terminals for said coil.
2. An electric coil comprising a heat-resistant, inorganic coil form, spaced portions of said coil form having areas coated with a platinum-silver paint to form conducting areas, a winding of wire surrounding said coil form and extending over the conducting areas and the portion therebetween with bare end turns of the winding overlying at least a portion of said conducting areas and a coating of platinum-silver paint over said bare end turns of the winding to thereby rigidly fasten the coil to the coil form.
3. An electric coil comprising a heat-resistant, inorganic coil form, spaced portions of said coil form having areas coated with a highly conductive material to form conducting areas, a wire winding surrounding said coil form and extending over the conducting areas and the portion therebetween with bare end turns of the winding overlying at least a portion ofsaid conducting areas and a coating of highly conductive material over said bare end turns of the winding to thereby rigidly fasten the coil to the coil form.
4. An electric coil comprising a heat-resistant, inorganic coil form, spaced portions of said coil form having areas coated with a highly conductive material to form conducting areas, a winding on said coil form over the conducting areas and the portion therebetween with bare end turns of the winding overlying at least a portion of said conducting areas and a coating of highly conductive material over said bare end turns of the winding to thereby rigidly fasten the coil to the coil form, anda resilient terminal secured to said coil form and in contact with the conducting area thereon.
ALVAH O. ERICKSBERG. JOSEPH T. OSTERMAN.
REFERENCES CITED The following references are of record in the file of this patent:
UNITED STATES PATENTS
US611788A 1944-10-07 1945-08-21 Electric coil Expired - Lifetime US2434492A (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
US611788A US2434492A (en) 1944-10-07 1945-08-21 Electric coil

Applications Claiming Priority (2)

Application Number Priority Date Filing Date Title
US557710A US2434511A (en) 1944-10-07 1944-10-07 Method of making electric coils
US611788A US2434492A (en) 1944-10-07 1945-08-21 Electric coil

Publications (1)

Publication Number Publication Date
US2434492A true US2434492A (en) 1948-01-13

Family

ID=27071509

Family Applications (1)

Application Number Title Priority Date Filing Date
US611788A Expired - Lifetime US2434492A (en) 1944-10-07 1945-08-21 Electric coil

Country Status (1)

Country Link
US (1) US2434492A (en)

Cited By (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2551864A (en) * 1947-07-14 1951-05-08 Mcgraw Electric Co Method of coating and impregnating an electrical device
US2575140A (en) * 1948-12-29 1951-11-13 Bendix Aviat Corp Ignition device and parts thereof
US20040082179A1 (en) * 2002-10-23 2004-04-29 Murata Manufacturing Co., Ltd. Method for forming metal coating and method for manufacturing chip electronic components

Citations (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US1767715A (en) * 1927-02-19 1930-06-24 Central Radio Lab Electrical resistance
US1847653A (en) * 1928-03-12 1932-03-01 Technidyne Corp Manufacture of resistance units
US1981115A (en) * 1928-12-14 1934-11-20 Murphy Edmund Guyer Vacuum tube

Patent Citations (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US1767715A (en) * 1927-02-19 1930-06-24 Central Radio Lab Electrical resistance
US1847653A (en) * 1928-03-12 1932-03-01 Technidyne Corp Manufacture of resistance units
US1981115A (en) * 1928-12-14 1934-11-20 Murphy Edmund Guyer Vacuum tube

Cited By (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2551864A (en) * 1947-07-14 1951-05-08 Mcgraw Electric Co Method of coating and impregnating an electrical device
US2575140A (en) * 1948-12-29 1951-11-13 Bendix Aviat Corp Ignition device and parts thereof
US20040082179A1 (en) * 2002-10-23 2004-04-29 Murata Manufacturing Co., Ltd. Method for forming metal coating and method for manufacturing chip electronic components

Similar Documents

Publication Publication Date Title
US2434511A (en) Method of making electric coils
US2307561A (en) Terminal construction for electrical devices
US2961625A (en) Thermistor probe
JP6246063B2 (en) Spark plug
US2458748A (en) Hermetic seal for electric terminals and the like
US3214719A (en) Thermistor device
US2389018A (en) Terminal fastening for electrical capacitors
US3946290A (en) High tension ceramic condenser
US3443251A (en) Discoidal feed-through capacitors
US2434492A (en) Electric coil
US2253577A (en) Resistance device
US2253026A (en) Electrical condenser
US2552193A (en) Heating device
US4456900A (en) High frequency coil
US3065436A (en) Sheathed heating element
US2663827A (en) Radio frequency current transformer
JPH09297069A (en) Temperature detecting sensor
US2031846A (en) Electric oscillation circuit
US3020456A (en) Electrical capacitors and method of production
US4251792A (en) Thermistor bonded to thermally conductive plate
US2389915A (en) Resistor device
US1975870A (en) Indirectly heated cathode
US1364080A (en) Ballasting device
US2888618A (en) Dry plate rectifier assemblies
US3002136A (en) Electrical circuit component having resilient wound sleeve