US2244548A - Resistor and method for making same - Google Patents
Resistor and method for making same Download PDFInfo
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- US2244548A US2244548A US294167A US29416739A US2244548A US 2244548 A US2244548 A US 2244548A US 294167 A US294167 A US 294167A US 29416739 A US29416739 A US 29416739A US 2244548 A US2244548 A US 2244548A
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- resistance element
- insulating tube
- cement
- terminal conductors
- resistor
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01C—RESISTORS
- H01C1/00—Details
- H01C1/14—Terminals or tapping points or electrodes specially adapted for resistors; Arrangements of terminals or tapping points or electrodes on resistors
- H01C1/146—Terminals or tapping points or electrodes specially adapted for resistors; Arrangements of terminals or tapping points or electrodes on resistors the resistive element surrounding the terminal
-
- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01B—CABLES; CONDUCTORS; INSULATORS; SELECTION OF MATERIALS FOR THEIR CONDUCTIVE, INSULATING OR DIELECTRIC PROPERTIES
- H01B1/00—Conductors or conductive bodies characterised by the conductive materials; Selection of materials as conductors
-
- Y—GENERAL 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
- Y10—TECHNICAL SUBJECTS COVERED BY FORMER USPC
- Y10T—TECHNICAL SUBJECTS COVERED BY FORMER US CLASSIFICATION
- Y10T29/00—Metal working
- Y10T29/49—Method of mechanical manufacture
- Y10T29/49002—Electrical device making
- Y10T29/49082—Resistor making
- Y10T29/49087—Resistor making with envelope or housing
- Y10T29/49098—Applying terminal
Definitions
- My invention relates in general to resistor units and more particularly to resistor units which have terminal conductors mechanically and electrically connected thereto, and the method of making the same.
- An object of my invention is the provision of protecting a resistance element by mounting the element in an insulating tube and then fastening the resistance element in the tube.
- Another object of my invention is the provision of mounting a resistance element in an insulating tube and of electrically and mechanically connecting the terminal conductors to the end surfaces of the resistance element and of mechanically connecting the terminal conductors and the resistance element in the insulating tube.
- Another object of my invention is the provision of mounting a resistance element in a hollow insulating tube and of sealing the end of the tube with water-repellant material.
- Another object of my invention is the provision of surrounding the resistance element with a suitable water-repellant material to prevent the moisture from affecting the electrical characteristics ofthe resistance element.
- Another object of my invention is the provision' of mechanically strengthening the connection between the terminal conductors and the end surfaces of the resistance element.
- Another object of my invention is the provision of a resistor unit having an excellent connection between the terminal conductors and the resistance element with a substantially constant and fixed minimum resistance.
- Another object of my invention is the provision of an improved electrical and mechanical connection between the terminal conductors and the ends of the resistance element.
- Figure 1 illustrates a resistor unit made in accordance with the provision of my invention, a portion of the resistor unit being cut away at one end to show its internal construction;
- Figure 2 shows an end view of a resistance element of my resistor unit
- Figure 3 shows a side elevational view of the resistor unitin Figure2;
- Figure L shows a side elevational view of a hollow insulating tube into which the resistance element may be mounted
- Figure 5 is an end view of the hollow insulatin tube shown in'Fimu'e 4;-
- Figure 6 is a side view of a terminal conductor adapted to be connected to the end surface of the resistance element
- Figure 7 is a view of a terminal conductor having cement material upon the abutting end thereof, preparatory to insertion in the hollow insulation tube;
- Figure 8 is a cross-sectional view of my resistor unit as it appears during the final stages of the process of construction thereof;
- Figure 9 is a cross-sectional view of a modified form of my resistor unit as it appears during the process of manufacture thereof;
- Figure 10 is a view similar to Figure 9 and shows my modified resistor unit as it appears during a next subsequent operation of its manufacture;
- Figure 11 is a cross-sectional view similar to Figures 9 and 10 and shows the construction of my resistor unit as it appears when finally constructed;
- Figure 12 is a cross-sectional view taken along the line -
- my resistor unit is indicated generally by the reference character 20 and comprises a resistance element 2
- the abutting ends of the terminal conductors 23 may be provided with an enlarged head 24 such as, for example, bydeforming the end of the terminal conductor.
- the views in the drawing are an enlargement of the resistor units from which the illustrations were made and the terminal conductors 23 appear somewhat large in diameter but in actual practice the terminal conductors are smaller in diameter and are readily bendable to facilitate easy connection to electrical circuits.
- the insulating tube 22 may be made of any suitable insulating material and constructed with sufficient wall thickness and strength to keep it from crushing when being handled and installed. In actual practice, I preferably construct the insulating tube of ceramic material having a low porosity. As an alternative, the insulating tube 22 may be constructed of glass or a phenol con-. densation product such for example as Bakelite.
- may be of any desired shape and size and may comprise any suitable material having the desirable characteristics.
- the resistance element may comprise a small rod of porcelain or glass having a film of conducting material like graphite, colloidal graphite, or amorphous carbon deposited thereon.
- may'com prise any suitable conducting material mixed with a fine insulating filler like silica and a cementing bond to form a homogenous structure.
- the resistance values of the resistance element may vary in the order of one-tenth ohm to a thousand mehohms, carrying relatively small currents of one thousand milliamperes or less.
- comprising a .homogenous structure molded into rods as illusamorphous carbon mixed with a fine insulating filler like silica and a cementing bond into a homogenous structure.
- the cementing bond may be Bakelite or any other suitable phenol condensation produce.
- is in a green state, meaning that the Bakelite or phenol condensation 'produce bond of the resistance element has not set, or in other words has not been polymerized.
- is to heat it to polymerization and set the bond.
- the next step of my invention is to insert the resistance element 2
- a paste or cement consisting of substantially graphite, 50% Bakelite resin or phenol condensation product, and enough alcohol to make the cement paste-like.
- the cement or paste may be applied in the ends of the insulating tube 22 in one of three alternative manners.
- the preferred way is to dip the head 24 of the terminal conductors into the paste, collecting a certain amount thereon as indicated in Figure '7, and then inserting same into the opposite ends of the hollow insulating tube 22such as shown in Figure 8 with the abutting heads 24 pressing against the end surfaces of the resistance element 2 I.
- the paste or cement fills the ends of the insulating tube 22.
- paste would be to first insert the heads of the terminal conductors in the opposite ends of the hollow insulating tube 22 against the end surfaces of the resistance element 2
- Another method would be to fill the ends of the insulating tube 22 with the cement or paste and then push the .terminal conductors in through the paste or cement until the head 24 engages the end surfaces of the resistance element.
- , after it is applied in the ends of the insulating tube 22, is set or fixed by heating the entire combination as shown in Figure 8 to a temperature in the neighborhood of 150 to 170 degrees centigrade for approximately one-half an hour.
- the cement or paste has a greater conductivity than that of the resistance element 22 and makes a good electrical contact between the terminal conductors and the end surfaces of the resistance element with a substantially constant and fixed minimum resistance.
- the cement or paste permeates the pores upon the ends of the resistance element and produces a good mechanical connection between the terminal conductors chanically and electrically connecting the terminal conductors 22 to the end surfaces of .the resistance element 2
- is slightly smaller in diameter than the internal diameter of the insulating tube 22 which leaves a circumferential air space about the resistance element within the insulating tube 22.
- a suitable water-repellant material indicated by the reference 26 which may beof any one of three types: namely, a solid, 9. semi-solid, or a liquid of low viscosity.
- Suitable solid materials may comprise, although not limited thereto, paramne hydro-carbons of high molecular weight, or synthetic resin such as chlorinated diphenyls or para-coumarineindene.
- Suitable semi-solid materials may comprise, although not limited thereto. plastic pitches.
- Sutiable liquids may comprise, although not limited thereto, an hydrous butyl stearate or chlorinated diphennyls of low chlorine content.
- the waterrepellant material keeps the moisture of the at-. niosphere from affecting the electrical characteristic of the resistance elements.
- a solid or semi-solid material is used, it is heated to form should of low viscosity.
- the assembly as shown in Figure 8 is immersed in a water-repellent material under vacuum to evacuate .the air from the assembly.
- the material When a solid or semi-solid water-repellant material is em- Dloyed the material may be heated up to degrees to degrees centigrade and the units as shown in Figure 8.may remain immersed for a P riod of from 15 to 20 minutes. The vacuum is subsequently broken with the resistance units still submerged, and with the re-establishment oi atmospheric pressure, the water-repellant material flows through the pores in the cement 25 until it completely fills the void spaces including not only the circumferential space around the resistance element inside of the insulating tube but also the pores of the cement 25. After the resistance elements are removed from the waterrepellant material, the water-re'pellant material contained in the void spaces solidifies, producing the resistor shown in Figure 1 of the drawing.
- the sealins material Il may comprise a ceramic water-repellant material or a resin water-repellantmateriai.
- the ceramic sealing materlalfl maybesetorhardenedbybaking the assembly to approximately 100 degree centigrade for thirty or forty-five minutes, or it may be set or hardened by air' drying without heat.
- the resin sealing material may be applied by melting samewitha flame and allowinsaportiontodrop in the open end spaces of the insulating tube. which readily solidifies upon cooling.
- the unit is immersed in the heated or liquid water-repellant material under vacuum as pre-' viously described which fills the void spaces between the reslstance 2i and the insulating tube II as well as the pores of the cement material 2! and the sealing material 8
- the resin sealing material it is preferable to immerse the assembly as shown in Figure and fill the void spaces with the wa'ter-repellant material 26 prior to scaling the ends of the-tube, as the resin sealing material does not allow the water-repellant material 26 to go therethrough as readily as the ceramic sealing material.
- the method of constructing a resistor. unit which comprises the steps of molding in a green state a heat setting phenol condensation product having finely distributed electrical conducting particles into a resistance element having end surfaces, heating the molded resistance element g to set and harden same, providing an insulating tube of greater length than the resistance element to receive the'latter with space in both ends thereof and with a small clearance space minal conductors in the applied cement to elec-' trically connect the terminal conductors to the end surfaces of the resistance element, heating the insulating tube, the resistance element and the applied cement with the abutting ends of the terminal conductors embedded therein to set and harden the cement to electrically and mechanically connect the terminal conductors.
- the method of constructing a resistor unit which comprises the'steps of making a resistance element having end surfaces. providing an insulating tube ofgreater length than the resistance element to receive the latter with space in both ends thereof and with a small clearance space between the resistance elementandthe insulating tube.
- each said end surface of the resistance element a terminal conductor with an abutting end smaller than the opening in the insulating tube, providing a heat setting cement having finely distributed electrical conducting particles and having a greater electrical conductivity than the resistance element; applying the cement in the space in both ends of the insulating tube to each said end surface of the resistance element -and embedd the abuttin end of each of said terminal conductors in the applied cement to electrically connect the terminal conductors to the end surfaces of the re.- sistance element, heating the insulating tube, the resistance element and the applied cement with the abutting ends of the terminal conductors embedded therein tgx'set and harden the.
- a resistance elementz'having end surfaces which comprises the steps of making a resistance elementz'having end surfaces, providing an insulating tube of greater length than the resistance element to receive the latter with space in-both endsthereof and with a small clearancespace between the resistance element and the insulat ing tube, providing for each said end surface of the resistance element a bendable termlnalcon the applied cement with the abutting ends of the terminal conductors embedded therein to set and harden "the cement to electrically and mechanically connect the terminal conductors to the end surfaces of the resistance element and to mechanically connect the terminal conductors and the resistance element in the insulating 2,244,548 3.
- the method of constructing a resistor unit sistance element and to mechanically connect the terminal conductors and the resistance element in the insulating tube providing an insulating material and applying same into the remaining outermost space in both ends of the insulating tube to seal the ends of the tube, immersing the combined resistor unit in melted water-repellant material under vacuum to create voids in the unit by evacuating through the pores of the ,unit the air from the small clearance space between the resistance element and the insulating tube as well as from the pores themselves, releasing the vacuum to fill the voids with the melted water-repellant material, and removing the resistor unit from the melted water-repellent material and allowing the material in the resistor unit to solidify.
- the method of constructing a resistor unit which comprises the steps of molding in a green state a heat setting phenol condensation product having finely dlstributed electrical conducting particles into a resistance element having end surfaces, heating the molded resistance element to set and harden same, providing an insulating tube of greater length than the resistance element to .receive the latter with space in both ends thereof and with a small clearance tube, immersing the combined resistor unit'ifF melted water-repellent material under vacuum to create voids in the unit by evacuating through the pores of the unit the air from the small clearance space between the resistance element and theinsulating tube as well as from the pores themseives, releasing the vacuum to fill the voids with the melted water-repellent material, and removing the resistor unit from the melted water-repellent material and allowing the material in the resistor unit to solidify.
- the method of constructing a resistor unit which comprises the steps of making a resistance element having end surfaces, providing an insulating tube of greater length than the resistance element to receive the latter with space in both ends thereof and with a small clearance space between the resistance element and the insulating tube, providing for, each said end surface of the resistance element a terminal conductor with an abuttingend smaller than the opening in the insulating tube, providing a heat setting cement .having finely distributed electrical conducting particles and having a greater electrical conductivity than the resistance element, applying the cement in the innermost part of the space in both ends of the insulating tube to each said end surface of the resistance element and embedding the abutting end of each of said terminal conductors in the applied cement to electrically connect the terminal conductors to the end surfaces of the resistance element, heating the insulating tube, the resistance-element and the applied cement with the abutting ends of the terminal conductors embedded therein to set.
Description
June 3, 1941. G, BENKELMAN 2,244,548
RESISTOR AND METHOD'FOR MAKING SAME Filed Sept. 9, 1939 562 Haj 1N VENTOR.
66 1/ BY 67m flank/ma ATTORNEY.
new... 3, 1941 RESISTOR AND METHOD FOR MAKING SAME Glen F. Benkelman, Cleveland, Ohio, assignor to Continental Carbon, Inc.
Application September 9, 1939, Serial No. 294,167
Claims.
My invention relates in general to resistor units and more particularly to resistor units which have terminal conductors mechanically and electrically connected thereto, and the method of making the same.
An object of my invention is the provision of protecting a resistance element by mounting the element in an insulating tube and then fastening the resistance element in the tube. Another object of my invention is the provision of mounting a resistance element in an insulating tube and of electrically and mechanically connecting the terminal conductors to the end surfaces of the resistance element and of mechanically connecting the terminal conductors and the resistance element in the insulating tube.
Another object of my invention is the provision of mounting a resistance element in a hollow insulating tube and of sealing the end of the tube with water-repellant material.
Another object of my invention is the provision of surrounding the resistance element with a suitable water-repellant material to prevent the moisture from affecting the electrical characteristics ofthe resistance element.
Another object of my invention is the provision' of mechanically strengthening the connection between the terminal conductors and the end surfaces of the resistance element.
Another object of my invention is the provision of a resistor unit having an excellent connection between the terminal conductors and the resistance element with a substantially constant and fixed minimum resistance.
Another object of my invention is the provision of an improved electrical and mechanical connection between the terminal conductors and the ends of the resistance element.
Other objects and a fuller understanding of my invention may be had by referring to the following description and claims, taken in conjunction with the accompanying drawing, in which:
Figure 1 illustrates a resistor unit made in accordance with the provision of my invention, a portion of the resistor unit being cut away at one end to show its internal construction;
Figure 2 shows an end view of a resistance element of my resistor unit;
Figure 3 shows a side elevational view of the resistor unitinFigure2;'
Figure Lshows a side elevational view of a hollow insulating tube into which the resistance element may be mounted;
Figure 5 is an end view of the hollow insulatin tube shown in'Fimu'e 4;-
Figure 6 is a side view of a terminal conductor adapted to be connected to the end surface of the resistance element;
Figure 7 is a view of a terminal conductor having cement material upon the abutting end thereof, preparatory to insertion in the hollow insulation tube;
Figure 8 is a cross-sectional view of my resistor unit as it appears during the final stages of the process of construction thereof;
Figure 9 is a cross-sectional view of a modified form of my resistor unit as it appears during the process of manufacture thereof;
Figure 10. is a view similar to Figure 9 and shows my modified resistor unit as it appears during a next subsequent operation of its manufacture;
Figure 11 is a cross-sectional view similar to Figures 9 and 10 and shows the construction of my resistor unit as it appears when finally constructed; and
Figure 12 is a cross-sectional view taken along the line -|I-|2 of Figure 11.
With reference to Figure 1 of the drawing, my resistor unit is indicated generally by the reference character 20 and comprises a resistance element 2|, mounted in an insulating tube 22 with terminal conductors 23 connected to the opposite end surfaces of the resistance element 2| by suitable cement material indicated by the reference character 25. As illustrated, the abutting ends of the terminal conductors 23 may be provided with an enlarged head 24 such as, for example, bydeforming the end of the terminal conductor. The views in the drawing are an enlargement of the resistor units from which the illustrations were made and the terminal conductors 23 appear somewhat large in diameter but in actual practice the terminal conductors are smaller in diameter and are readily bendable to facilitate easy connection to electrical circuits.
The insulating tube 22 may be made of any suitable insulating material and constructed with sufficient wall thickness and strength to keep it from crushing when being handled and installed. In actual practice, I preferably construct the insulating tube of ceramic material having a low porosity. As an alternative, the insulating tube 22 may be constructed of glass or a phenol con-. densation product such for example as Bakelite.
The' resistance element 2| may be of any desired shape and size and may comprise any suitable material having the desirable characteristics. In one form of my invention, the resistance element may comprise a small rod of porcelain or glass having a film of conducting material like graphite, colloidal graphite, or amorphous carbon deposited thereon. In another form, the resistance element 2| may'com prise any suitable conducting material mixed with a fine insulating filler like silica and a cementing bond to form a homogenous structure. The resistance values of the resistance element may vary in the order of one-tenth ohm to a thousand mehohms, carrying relatively small currents of one thousand milliamperes or less. I will describe my' invention by utilizing the resistance element 2| comprising a .homogenous structure molded into rods as illusamorphous carbon mixed with a fine insulating filler like silica and a cementing bond into a homogenous structure. The cementing bond may be Bakelite or any other suitable phenol condensation produce. In the initial stages this resistance element 2| is in a green state, meaning that the Bakelite or phenol condensation 'produce bond of the resistance element has not set, or in other words has not been polymerized. The final step in making the resistance element 2| is to heat it to polymerization and set the bond.
The next step of my invention is to insert the resistance element 2| in the hollow insulating tube 22 and to electrically and mechanically connect the terminal conductors 23 to the end surfaces of the resistance element 2| and to mechanically connect the terminal conductors and accomplished by utilizing a paste or cement consisting of substantially graphite, 50% Bakelite resin or phenol condensation product, and enough alcohol to make the cement paste-like. In making the electrical and mechanical connections, the cement or paste may be applied in the ends of the insulating tube 22 in one of three alternative manners. The preferred way is to dip the head 24 of the terminal conductors into the paste, collecting a certain amount thereon as indicated in Figure '7, and then inserting same into the opposite ends of the hollow insulating tube 22such as shown in Figure 8 with the abutting heads 24 pressing against the end surfaces of the resistance element 2 I. In this manner, the paste or cement fills the ends of the insulating tube 22. paste would be to first insert the heads of the terminal conductors in the opposite ends of the hollow insulating tube 22 against the end surfaces of the resistance element 2|, after which the paste may be inserted therein by any suitable means. Another method would be to fill the ends of the insulating tube 22 with the cement or paste and then push the .terminal conductors in through the paste or cement until the head 24 engages the end surfaces of the resistance element. The ce- Another way of applying the cement or ment 2|, after it is applied in the ends of the insulating tube 22, is set or fixed by heating the entire combination as shown in Figure 8 to a temperature in the neighborhood of 150 to 170 degrees centigrade for approximately one-half an hour. The cement or paste has a greater conductivity than that of the resistance element 22 and makes a good electrical contact between the terminal conductors and the end surfaces of the resistance element with a substantially constant and fixed minimum resistance. The cement or paste permeates the pores upon the ends of the resistance element and produces a good mechanical connection between the terminal conductors chanically and electrically connecting the terminal conductors 22 to the end surfaces of .the resistance element 2| and for mechanically connecting the terminal conductors and the resistance element in the insulating tube 22. This means that after the cement 25 is set the terminal conductors 22 may withstand a considerable amount of pull without disturbing the mechanical and electrical connections.
As shown in Figures 1 and 8, the resistance element 2| is slightly smaller in diameter than the internal diameter of the insulating tube 22 which leaves a circumferential air space about the resistance element within the insulating tube 22. The next operation in the'manufacture of my resistor unit is to ill] the circumferential space with a suitable water-repellant material indicated by the reference 26 which may beof any one of three types: namely, a solid, 9. semi-solid, or a liquid of low viscosity. Suitable solid materials may comprise, although not limited thereto, paramne hydro-carbons of high molecular weight, or synthetic resin such as chlorinated diphenyls or para-coumarineindene. Suitable semi-solid materials may comprise, although not limited thereto. plastic pitches. Sutiable liquids may comprise, although not limited thereto, an hydrous butyl stearate or chlorinated diphennyls of low chlorine content. The waterrepellant material keeps the moisture of the at-. niosphere from affecting the electrical characteristic of the resistance elements. When a solid or semi-solid material is used, it is heated to form should of low viscosity. In order to fill the circumferential air space around the resistance element 2| in the hollow insulating tube 22, the assembly as shown in Figure 8 is immersed in a water-repellent material under vacuum to evacuate .the air from the assembly. When a solid or semi-solid water-repellant material is em- Dloyed the material may be heated up to degrees to degrees centigrade and the units as shown in Figure 8.may remain immersed for a P riod of from 15 to 20 minutes. The vacuum is subsequently broken with the resistance units still submerged, and with the re-establishment oi atmospheric pressure, the water-repellant material flows through the pores in the cement 25 until it completely fills the void spaces including not only the circumferential space around the resistance element inside of the insulating tube but also the pores of the cement 25. After the resistance elements are removed from the waterrepellant material, the water-re'pellant material contained in the void spaces solidifies, producing the resistor shown in Figure 1 of the drawing. In this type of construction, the cement connection which holds the heads 24 to the end surfaces of the resistance element 2!, is materially strengthened mechanically by reason of the fact that .the cement is also anchored to the inside of the insulating tube. In Figures 9, 10, ii, and 12 I show a modified arrangement of my invention in that the insu-. lating tube, which is identified in these views by the reference character 30, is made longer than the insulating tube shown in the previous views of the drawing. The method as shown in Figure 9 of mounting the resistance unit 2| in the elongated tube 30 and of mechanically and electrically connecting the terminal conductors 21 to the end surfaces of the resistance element 2i and of mechanically connecting the terminal conductors and the resistance element 2| to the inside of the insulating tube II by the "applying V of cement in the innermost part of the open ends of the insulating tube II is theme as described with reference to the previous views of the drawing. After invention is constructed as shown in Figure 9 the outermost part of the speca in the ends of the insulating tube II are filled with a suitable hardening water-repeilant material {I toseai the endsof the tube from moisture. The sealins material Il may comprise a ceramic water-repellant material or a resin water-repellantmateriai. The ceramic sealing materlalfl maybesetorhardenedbybaking the assembly to approximately 100 degree centigrade for thirty or forty-five minutes, or it may be set or hardened by air' drying without heat. The resin sealing material may be applied by melting samewitha flame and allowinsaportiontodrop in the open end spaces of the insulating tube. which readily solidifies upon cooling. After the seaiingmaterial II is applied as shown in Figure 10, the unit is immersed in the heated or liquid water-repellant material under vacuum as pre-' viously described which fills the void spaces between the reslstance 2i and the insulating tube II as well as the pores of the cement material 2! and the sealing material 8|, producing theresistor as shown in Figure 11. when using the resin sealing material it is preferable to immerse the assembly as shown in Figure and fill the void spaces with the wa'ter-repellant material 26 prior to scaling the ends of the-tube, as the resin sealing material does not allow the water-repellant material 26 to go therethrough as readily as the ceramic sealing material.
Although I have described nrv invention with a certain degree of particularity, it is understood that the present disclosure has been made only by way of example-and that numerous changes in the details of construction and the combination and arrangement of parts may be resorted to without departing from the spirit and the scope of the invention as hereinafter claimed.
I claim as my invention:
l. The method of constructing a resistor. unit which comprises the steps of molding in a green state a heat setting phenol condensation product having finely distributed electrical conducting particles into a resistance element having end surfaces, heating the molded resistance element g to set and harden same, providing an insulating tube of greater length than the resistance element to receive the'latter with space in both ends thereof and with a small clearance space minal conductors in the applied cement to elec-' trically connect the terminal conductors to the end surfaces of the resistance element, heating the insulating tube, the resistance element and the applied cement with the abutting ends of the terminal conductors embedded therein to set and harden the cement to electrically and mechanically connect the terminal conductors.
to the end surfaces of the resistance element and to mechanically connect the terminal conductors and the resistance element in the insulatin tube, immersing the combined resistor unit in melted'water-repellant material under vacuum to create voids in the unit by evacuating through the pores of the unit the air from the small clearance space between the resistance element and the insulating tube as well as from'the pores themselves, releasing the vacuum to fillthe voids with the melted water-repellent material, and removing the resistor imit from the melted water-repellent material and allowing the material in the resistor unit to solidify.-
2. The method of constructing a resistor unit which comprises the'steps of making a resistance element having end surfaces. providing an insulating tube ofgreater length than the resistance element to receive the latter with space in both ends thereof and with a small clearance space between the resistance elementandthe insulating tube. providing for each said end surface of the resistance element a terminal conductor with an abutting end smaller than the opening in the insulating tube, providing a heat setting cement having finely distributed electrical conducting particles and having a greater electrical conductivity than the resistance element; applying the cement in the space in both ends of the insulating tube to each said end surface of the resistance element -and embedd the abuttin end of each of said terminal conductors in the applied cement to electrically connect the terminal conductors to the end surfaces of the re.- sistance element, heating the insulating tube, the resistance element and the applied cement with the abutting ends of the terminal conductors embedded therein tgx'set and harden the.
cement to electrically and mechanically connect the terminal conductors to the end surfaces of the resistance element and to mechanically con- ,nect the terminal conductors and the resistance.
element in the insulating tube, immersing the combined resistor unit in melted water-repellant material imder vacuum to create voids in the unit by evacuating through the pores of the unit the air from the small clearance space between the resistance element and the insulating tube as well as from the pores themselves. releasing the vacuum to fill the voids with the melted water-repellant material, and removing the resistor unit from the melted water-repellant material and allowing the material in the resistor unit to solidify.
which comprises the steps of making a resistance elementz'having end surfaces, providing an insulating tube of greater length than the resistance element to receive the latter with space in-both endsthereof and with a small clearancespace between the resistance element and the insulat ing tube, providing for each said end surface of the resistance element a bendable termlnalcon the applied cement with the abutting ends of the terminal conductors embedded therein to set and harden "the cement to electrically and mechanically connect the terminal conductors to the end surfaces of the resistance element and to mechanically connect the terminal conductors and the resistance element in the insulating 2,244,548 3. The method of constructing a resistor unit sistance element and to mechanically connect the terminal conductors and the resistance element in the insulating tube, providing an insulating material and applying same into the remaining outermost space in both ends of the insulating tube to seal the ends of the tube, immersing the combined resistor unit in melted water-repellant material under vacuum to create voids in the unit by evacuating through the pores of the ,unit the air from the small clearance space between the resistance element and the insulating tube as well as from the pores themselves, releasing the vacuum to fill the voids with the melted water-repellant material, and removing the resistor unit from the melted water-repellent material and allowing the material in the resistor unit to solidify.
5. The method of constructing a resistor unit which comprises the steps of molding in a green state a heat setting phenol condensation product having finely dlstributed electrical conducting particles into a resistance element having end surfaces, heating the molded resistance element to set and harden same, providing an insulating tube of greater length than the resistance element to .receive the latter with space in both ends thereof and with a small clearance tube, immersing the combined resistor unit'ifF melted water-repellent material under vacuum to create voids in the unit by evacuating through the pores of the unit the air from the small clearance space between the resistance element and theinsulating tube as well as from the pores themseives, releasing the vacuum to fill the voids with the melted water-repellent material, and removing the resistor unit from the melted water-repellent material and allowing the material in the resistor unit to solidify. 4. The method of constructing a resistor unit which comprises the steps of making a resistance element having end surfaces, providing an insulating tube of greater length than the resistance element to receive the latter with space in both ends thereof and with a small clearance space between the resistance element and the insulating tube, providing for, each said end surface of the resistance element a terminal conductor with an abuttingend smaller than the opening in the insulating tube, providing a heat setting cement .having finely distributed electrical conducting particles and having a greater electrical conductivity than the resistance element, applying the cement in the innermost part of the space in both ends of the insulating tube to each said end surface of the resistance element and embedding the abutting end of each of said terminal conductors in the applied cement to electrically connect the terminal conductors to the end surfaces of the resistance element, heating the insulating tube, the resistance-element and the applied cement with the abutting ends of the terminal conductors embedded therein to set. and harden the cement to electrically and mechanically connect the terminal conductors to the end surfaces of the reparticles and having a greater electrical conductivity than the resistance element, applying the cement in the innermost part of the space in both ends of the insulating tube to each said end surface of the resistance element and embedding the abutting end of each of said terminal conduc'torsin the applied cement to electrically connect the terminal conductors to the end surfaces of the resistance element, heating the insulating tube, the resistance element and the applied cement with the abutting ends of the terminal conductors embedded therein to set and harden the cement to electrically and mechanically connect the terminal conductors to the end surfaces of the resistance element and to mechanically connect the terminal conductors and the resistance element in the insulating tube, providing an insulating material and applying same into the remaining outermost space in both ends of the insulating tube to seal the ends of the tube, immersing the combined resistor unit in melted water-repellant material under vacuum to create voids in the 'unit by evacuating through thepores of the unit the air from the small clearance space between the resistance element and the insulating tube as well as from the pores themselves, releasing the vacuum to fill the voids with the melted waterrepellant material, and removing the resistor unit from the meltedwater-repellant material and ailowing the material in the resistor unit to solidify.
GLEN F. BENKELMAN.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
US294167A US2244548A (en) | 1939-09-09 | 1939-09-09 | Resistor and method for making same |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
US294167A US2244548A (en) | 1939-09-09 | 1939-09-09 | Resistor and method for making same |
Publications (1)
Publication Number | Publication Date |
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US2244548A true US2244548A (en) | 1941-06-03 |
Family
ID=23132195
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
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US294167A Expired - Lifetime US2244548A (en) | 1939-09-09 | 1939-09-09 | Resistor and method for making same |
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US (1) | US2244548A (en) |
Cited By (6)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2597338A (en) * | 1950-05-11 | 1952-05-20 | Wilkor Products Inc | Resistance |
US2660651A (en) * | 1952-07-26 | 1953-11-24 | Chicago Telephone Supply Corp | Electric switch |
US2728837A (en) * | 1953-04-21 | 1955-12-27 | Caruso Mario | Resistors |
US2806109A (en) * | 1954-03-19 | 1957-09-10 | Westinghouse Electric Corp | Arc resistant molded members and electrical apparatus embodying them |
US3307134A (en) * | 1959-12-14 | 1967-02-28 | Corning Glass Works | Encapsulated impedance element |
US5664320A (en) * | 1994-04-13 | 1997-09-09 | Cooper Industries | Method of making a circuit protector |
-
1939
- 1939-09-09 US US294167A patent/US2244548A/en not_active Expired - Lifetime
Cited By (6)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2597338A (en) * | 1950-05-11 | 1952-05-20 | Wilkor Products Inc | Resistance |
US2660651A (en) * | 1952-07-26 | 1953-11-24 | Chicago Telephone Supply Corp | Electric switch |
US2728837A (en) * | 1953-04-21 | 1955-12-27 | Caruso Mario | Resistors |
US2806109A (en) * | 1954-03-19 | 1957-09-10 | Westinghouse Electric Corp | Arc resistant molded members and electrical apparatus embodying them |
US3307134A (en) * | 1959-12-14 | 1967-02-28 | Corning Glass Works | Encapsulated impedance element |
US5664320A (en) * | 1994-04-13 | 1997-09-09 | Cooper Industries | Method of making a circuit protector |
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