US3074150A - Method of manufacturing electrical connectors - Google Patents

Description

Jan. 22, 1963 Q. BE'RG 3,074,150

METHOD OF MANUFACTURING ELECTRICAL CONNECTORS Original Filed Sept. 9, 1955 2 Sheets-Sheet 1 INVENTOR.

Quamm BERG Jan. 22, 1963 Q. BERG 3,074,150

METHOD OF MANUFACTURING ELECTRICAL CONNECTORS Original Filed Sept. 9, 1955 2 Sheis-Sheet 2 w as as m w% T1 3 \Y W 46V 55 90 90 q r Y 6 9o 60 m 660. 91 INVENTOR.

Ouemm BERG United States Patent Ofiice Patented Jan. 22, 1963 This invention is related to electrical connectors of the type which are used, in the form of a continuous strip of connectors, in machines which pressure-crimp the connectors individually onto wire conductors or the like. In preferred form, the subject connector is adapted to connect a lead wire to electrical elements with precision to embody them as useful components for electrical circuits (e.g., resistors, reactors, and capacitors). This application is a division of my copending application, Serial No. 536,893, filed September 9, 1955, now Patent No. 2,929,046.

Connectors in strip form have recently come into wide use as a consequence of inventions of V. E. Carlson (Patent No. 2,396,913) and W. S. Watts (application No. 514,214, filed December 14,1943) and successive developments of their associates F. L. Pierce, I. C. Macy, and myself. In those cases Where the connectors are to be used for permanently joining two or more conducting members, such strip generally comprises pairs of rolled-up laterally-opposed portions of sheet metal which form either cylindrical ferrules or channels, with an interal connection from the base of each channel to the next connector in the strip.

In such strip as known before the present invention, portions of the stock were stricken away to leave such joining portions of substantially lesser transverse extent than the adjoining parts of the connectors. In a copending application of F. L. Pierce there is shown a strip having successive terminals partially sheared from one another without waste and the joining portions weakened to facilitate final severing by tearing or shearing in automatic applicator machines with greatly increased life of shear blades and thus reducing cost of servicing such machines. This also avoided the necessity for precision die structures such as had been used to stamp out connecting portions of the strip prior to or during the pressure-crimping operation.

In my copending application, Serial No. 119,220, filed October 3, 1949, I disclose and claim continuous strips of electrical connector structures which can be indexed or moved by strip-feeding members although there are substantially no gaps between the connectors. These structures include turning outwardly one edge at the sides of the U-shaped portions so that this edge projects to form an abutment for indexing or driving means and generally consist of deforming the side walls of such U-shaped portions in various fashions to produce such abutments. With these novel indexing abutments, the cost of the connectors is reduced, as none of the sheet metal stock is wasted in the connector joining portions which would be cut out during use and discarded. Substantially all of the stock is incorporated into the connectors themselves. The present connector likewise achieves the advantages of full utilization of the entire strip stock, and the avoidance of the necessity of maintaining sharp shear edges in the applicator machines; but according to this invention, I have now discovered that the terminals can be made to provide their own shear within themselves and to avoid leaving of substan-v The importance of this is evident when it is remembered that the applicator machines must be located where the terminals are being applied, and in the possession of persons unfamiliar with their manufacture and proper maintenance. Sharpened cutting blades heretofore used on these structures required frequent adjustment, sharpening and/or replacement expensive in itself as well as limiting the time the machine was in operation, without having to be shut down for such servicing. Furthermore, such cutting means frequently left small burrs extending from the cut edge of the connectors, and it has been found distinctly advantageous to avoid such burrs in many applications, particularly in precision electrical resistors and radio frequency chokes.

The invention is applicable generally to the connecting of wires to circuit component elements, e.g., the resistance elements, choke coils etc., mentioned above. Such elements are commonly made in the form of wire helically wound onto a core of insulating material. This wirewound insulation or other circuit element which is to be subsequently connected into a circuit as a component thereof is referred to herein as electrical element. With lead wire connections made at each end of lengths of such elements, they become useful circuit components. The electrical values, e.g., resistance or reactance, of such components and consequently their performance in a given circuit are dependent on the active length of the element, that is, its length between the closest opposite end contacts with the connectors or the lead-in wires. In the broader aspects of this invention, it is concerned with the making of connections on circuit component elements other than resistance or reactance coils, e.g., paper-foil capacitors and even simple conductors.

My new connector-strips are used to make permanent lead-wire connections to such electrical elements, and this with speed, economy, precision, accuracy and electrical and mechanical security. It has been found to be distinctly advantageous, however, to avoid the tearing out or extrusion of burrs, during cutting of the end connector from the strip, as such burrs could, under certain conditions, damage a fragile circuit component element, or reduce the spacing from other circuit elements or otherwise be detrimental to the excellence of the connection.

It is, therefore, a general object of this invention to provide a continuous strip of electrical connectors which will hold together under the handling to which it must be subjected in manufacture, transit and use but from which individual connectors can be severed without need for sharp edged tools and with production of a connector, well adapted to join two conducting members with great precision accuracy, .and electrical and mechanical stability, even where one conducting member to be joined is a fragile electrical element.

Beyond this, it is an object to the invention to make connections with such precision and stability.

With these and other objects, which will be apparent, my invention provides a continuous strip of electrical connectors Which are in full edge contact with one another in the strip to maintain their parallelism while they are being subsequently severed, and which are joined in the strip by a thin section of metal spaced from the inner and outer faces of the strip, whereby each connector can be accurately severed from the strip without the use of sharp cutting members with greater precision than was known in the prior art, and this merely by the imposition of opposed, laterally oflF-set forces to the end connector and the adjacent connector of the strip to which it is attached.

It is also an important object to apply connectors from strip without the protrusion of any burrs, such as may 3 be acquired during the severing of connectors from the stri I accomplish these as well as other objects through the use of novel joining areas between the connectors in the strip. These areas are longitudinally of small dimension, and, laterally, they are substantially thinner than the sheet metal which comprises the connectors. In combination with this small joining area, this invention in preferred form utilizes a recessed area in the inner surface of the connector strip adjacent each such joining area. Other novel features in combination particularly adapt my invention to certain specific applications.

The aforesaid, and other objects will in part be pointed out in and will in part become apparent from the following specification and claims, taken in conjunction with the accompanying drawings.

In the drawings:

FIGURE 1 is an isometric view of upper die structures, a strip of sheet metal stock as it is formed into a continuous strip of connectors by such die structures, and lower die structures as are used in conjunction with the upper structures;

FIGURE ,2 is an axial longitudinal sectional view taken on the line 2-2 of FIGURE 1, with the die structures brought together'against the strip;

FIGURE 3 is an isometric view of a strip of connectors embodying this invention;

FIGURE 4 is an isometric View of a single connector as might be severed from a strip as'shown in FIGURE 4;

FIGURE 5 is a side elevational view of a strip as is shown in FIGURE 2, partially broken away to present an axial cross-section of this strip;

FIGURE 6 is an end elevation of a connector as is shown in FIGURE 3;

FIGURE 7 is a side view of the strip of connectors, electrical element, lead wire, and their assembly apparatus, the latter shown partially in cross-section;

FIGURE 8 is a right end elevational view of certain elements in FIGURE 6',

FIGURE 9 is a cross-section taken at the line 9-9 in FIGURE 7;

FIGURE 10 is a side elevation of a precision electrical circuit component, partially broken away and presented in axial cross section;

FIGURE 11 is an isometric view of an end connection of the component shown in FIGURE 10;

FIGURE 12 is a cross section taken at the line 12-12 in FIGURE 11.

Referring to FIGURE 1, a strip of sheet metal is shown disposed between an upper set of die structures 22 and a lower set of die structures 24, this strip 20 being successively worked, cut, and otherwise repeatedly reformed at various stages in the opposed die structures 22 and 24.

The lower die structures 24 include a generally flatsurfaced anvil 26, a lancing block 28 having a dihedral surface 29, and a U-ing or bending block 30 having a. curved cylindriform surface 32. For forming the preferred connector strip 46, two small peening forms 33 are on opposite sides of the surface 36 of the anvil 26.

The lancing block surface 29 at its ridge 34, is offset beneath the plane of the anvil surface 36 a distance less than the thickness of the sheet-metal strip 20 to be formed.

Cooperating with these surfaces are upper die structures 22 which include a lance 38 and a U-ing or curving punch 4%. A strip of sheet metal 26 indexed intermittently (from right to left in the drawings) between the repeatedly closed sets of die structures 22 and 24 is cut and bent from its originally flat stock form 42 into partially folded portion, comprised of two surfaces joining at an angle, which will be referred to as a dihedral 4d, and then bent further to form a continuous strip 46 of generally cylindriform, U-shaped structures which comprise, individually, electrical connectors 48.

Referring to FIGURES l and 2, the lance 38, in forming the dihedral 44, severs it at its trailing edge 56 from the flat stock 42, but for the vertex 52 of the dihedral 44 which is offset from said fiat stock 42 and partially severed therefrom. This particular forming operation thus serves the functions of forming the individual connector blanks 43, bending them generally into the form of a dihedral 4 as an intermediate step in their slitting from the continuous strip, leaving a joining area 54- of small cross-section, and, by virtue of first providing an offset 55 in the strip and then re-aligning the connector blanks 43 as they are further shaped to form connectors 48, providing a recessed area 56 in the strip 46 adjacent the joining areas 54.

The nature of this recess 56 and joining area 54 is best seen in FIGURE 2 taken in conjunction with FIGURE 5 and with FIGURES 3, 4 and 6, which latter figures present this area 54 after subsequent shearing. It is to be noted that the joining area is of relatively small cross-section, and, preferably, does not extend laterally into contact with either surface of the strip. Among the advantages accruing from this latter feature is the fact that the dimensions of each individual connector are well pro-established by the placement of said joining area 54; these connectors 48 are thereby adapted to be accurately severed from the strip without the use of sharp cutting means, but rather with the mere imposition of a lateral force between the end connector 48a and the strip 46 (FIGURES 3 and 5).

This shearing process is best seen in FIGURE 7, wherein the strip 46a, here in an inverted position, is seen disposed between an upper guiding and supporting member 58 and a lower supporting member 60. A third member, in practice one of two cooperating die structures, referred to herein as the upper crimping die 62, is abutted against the bottom (here turned upward) of the end connector 480 of the strip 46a, and the upper crimping die 62 and the strip supporting members 58 and 60' are driven transversely (vertically) relative to one another, and the end connector is thus slid or wiped ed the supported strip 46a. In effect, the supported strip provides the shearing edge for this severing actioni.e., the connectors shear against one another. In the lateral movement of the end connector 480 relative to the strip 46a the vertical end edges 67 of the side walls 68 of the end connector 480 slide along those 67:; of adjacent connector in the strip 46a, thus advantageously limiting the motion of the end conhector to a laterally shearing one and causing joining area 54 to be cleanly sheared rather than partially bent and torn off. The recessed area 56 previously described provides further assurance in that if by any chance this shearing should produce any burr it would be within this recess and within the thickness of the connector 480 as well as of that in the adjacent connector in the strip 46a.

Subsequent application of the end connector 480 to a fragile electrical element 64 and a lead wire 66 is seen in FIGURES 7 and 8 taken together. Referring to FIGURE 7, after being severed from the strip 46a the end connector 48c is held between the upper crimping die 62 and a lower crimping die 74, by virtue of sliding frictional engagement of the side walls 72 of this lower die '74 with the longitudinal end edges 70 of the connector 48c.

In application to an electrical element and a lead wire, as is shown in FIGURE 8, the severed end connector 48d is disposed between the crimping dies 62 and '72, with a fragile electrical circuit element 64 and a lead wire disposed opposite the end edges 70 of the connector dfib. Subsequent bringing together of the dies 62 and 72 encloses and compressively engages the electrical element 64 in the connector 48b and securely grips the lead wire between the end edges 76 of the connector.

The previously discussed recessed areas 56 in the strip 46, or 46a, provide recessed end edges 76 in the severed connector 480. In the connection 30 (FIGURE 9), seen partially in cross-section in the opposite-end connection 80a, these recessed edges '76 accommodate any burr which might conceivably be produced during the shearing of the connector from its strip, and thus preclude the cutting of the fragile wires 82 of the electrical element 64a.

The formation of the recessed edges 76 also serves to avoid sharp corners, which even though free from burrs might impose damaging shear stresses on the fragile wires 82 when the connections 8d are crimped thereon.

Referring again to FIGURE 7, it is seen that the connector 480 has a longitudinal dimension (length from left to right in FIGURE 7) great enough to permit the connector to grip a substantial length of the electrical element 64a. This entire area is substantially uniformly compressed onto the element 64a so that the element is securely gripped with a good electrical contact but without excessive pressure of the connector 430 on the fragile wires 82 (because of distribution of the gripping force over an area suflicient to preclude the damaging of these wires). Further, it is distinctly advantageous to have this longitudinal dimension great enough to provide a secure grip on a lead wire 66:: between the end edges 7d of the connector 4311. even though this lead wire 66a. does not extend to the inner edge 84 of the connector (note the connection 80a, FIGURE 10, also FZGURE 11). The inner edge 84 is thus relieved from great compression, and this produces a longitudinal gradient of pressure on the electrical element 64a which helps to protect it against damage, and this also avoids any danger of driving the cut end of the lead Wire into the electrical element 64a in the critical area which determines its active length. The length of the connector 48 also determines the leverage which the lead wire 66 can exert tending to pry open the connection, although ordinarily the rigidity of the connection is so much greater than the bending strength of the wire that this leverage is not a controlling factor. Yet another function served by the length of the connector 43 is the strengthening against flexure of the connections 80, 88a, which in turn enhances the electrical and mechanical stability of these connections.

It is to be noted that, in the preferred embodiment shown in the drawings, the strip of connectors 46 presents the general appearance of a channel and, more particularly, One with a rounded bottom. In certain applications, such as that described herein, this rounded con tour of the bottom of the connectors is distinctly advantageous in onder that the connectors can receive and snugly fit round fragile electrical elements without damaging them during crimping. The radius of curvature of the bottom inner surface of the connectors, or of the channel comprising a strip of connectors, is in present practice, slightly less than the outer radius of curvature of a round electrical element to be gripped therein. The reason for this is that the forces on the connector as it is driven along the side walls 72 and into the lower crimping die 74 tend to spread its bottom as said connector is driven around and about said element. It is to be understood, of course, that strips with other than rounded bottoms can be successfully used, with appropriate male and female crimping means, but it unnecessarily complicates the problem, when the element to be engaged is round. If the electrical elements to be used in the manufacture of circuit components were of a shape other than round, or if they were not fragile but were themselves sturdy structures, the cross-sectional shape of the connectors could be varied within broad limits providing that the generally channel-like form is adhered to.

With the round, fragile, electrical element to be connected in an embodiment of this invention and a lead were gripped between the longitudinal end edges (i.e., the longitudinally directed, laterally extreme end edges) of the connector or channel, the lateral inner peripheral dimension (i.e., from one such edge transversely around the inner surface to the other end edge along a section normal to the axis) must be such that secure compressive gripping of the lead wire can be acquired while the enclosed element is held with adequate but not destructive pressure; and that such adequate gripping pressure is reached after the lead wire has been gripped between the edges but before it has been weakened beyond the requirements of its use. When the crimping dies are at the end of their movement, the wire 66 should be substantially deformed between the edges 70 so that it is keyed against rotation and against axial pull-out. (Note FIGURES l1 and 12.) In order that the element 64 will not be scratched by the connector as it is being forced around the element during assembly (which could result in breakage of the fragile wires when the connector thereafter is peripherally compressed and worked or flowed beyond its yield point and thus given a permanent set to secure the lead wire and element) this peripheral dimension plus the diameter of the lead wire should be considerably greater than the compressed circumference of the electrical element used. With the dimensional relationships of connector, electrical element, and lead wire as shown in the accompanying drawings, this inner periphery is approximately four times the lateral Width of the rounded bottom portion of the inner surface of the connector measured at an altitude equal to one half said width above the bottom of the interior.

In crimping, the element 64 is initially of diameter sli htly greater than the said lateral width of the bottom portion of the connector and hence does not immediately bottom therein; but as the end edges 7t? of the connector are bent around in the die the Width is slightly increased and the element is pushed in toward the bottom. The lead wire is then gripped between the longitudinal end edges of the connector as the electrical element is enclosed thereby; and the connector is then finally compressed against the Wire until, finally, inelastic radial extrusion and compression of the connector sets walls thereof in a form to maintain a strong but well distributed gripping pressure on the enclosed element. A general expression for the width of the strip of sheet metal stock from which these preferred forms of connectors are made has been found to be pi times the sum of the outside diameter of the electrical element plus the thickness of the sheet metal stock minus the lead wire diameter, and 3 to 25 percent of the remainder added thereto to allow for compressive setting.

Although the 25% addition will ordinarily be more than necessary (and even larger excess can be used in extreme cases) it is permissible in my invention by reason of the crimping die set shown in FIGURE 7. As the pressure on the ferrule increases in the dies its frictional resistance against the die face increases so that instead of pinching off the wire, the compression tends to be relieved by thickening and extrusion of the metal in the Zone where the surfaces of the male and female dies meet. Unless lead wires in the form of wider more or less fiat, strips of metal were used, the connector itself would have an inner lateral periphery greater than three times the Width of the curved bottom inner surface thereof, said width being taken at a point one-half this width above the bottom of said inner surface.

Various advantages accrue from having the side edges of the connectors face-to-face in the strip and lying in the same plane. As previously discussed, this construction gives sliding support to the end connector as it is moved laterally across the strip for shearing and holds the align ment of the connector so that it is properly oriented in the crimping die. Of great interest is the fact that this alignment of the side walls of the connectors, in the strip, enables the size of the crimping die surfaces to be reduced and permits crimping of the connectors onto fragile electrical elements with much less danger of damage by reducing the necessary clearance between said elements and the die surfaces. Advantageously this clearance is only slightly greater than the thickness of the connector metal, but sufficient so that it does not bind on the core. This small clearance of the side of the element can be filled in by thickening of the connector by compression during crimping. These features permit much greater accuracy and precision of the crimping operation. Furthermore, this essentially cylindriform shape of the connectors obviates the risk of having relatively inwardly disposed portions of the side walls making contact, with high unit pressure, with the electrical element as it is enclosed by the connector during crimping.

A yet further advantage gained in the use of strips comprised of such aligned cylindriform connectors is the fact that the strip can bend in only one direction. The joining areas between connectors are strong enough to permit the strip being handled, that is, loaded onto applicator machines in the form of rolls of strip and the end of the strip fed through guiding and indexing mechanisms in the machines, the abutting relationship of the connectors in the strip enables them to behave as if they were rigid members when subjected to columnar loading, greatly facilitating their being accurately fed in an automatic applicator. Furthermore, this strip is wound onto reels with easily achieved neatness, as it bends in only one direction and resists twisting. In order to gain these and other advantages a new means of providing an abutment for indexing members to engage in feeding the strip in the machine, is herein provided.

In my previously referred to copending application Serial No. 119,220 I disclose and claim various embodiments of lateral deformations in the side walls of stripform connectors. -A specific embodiment of this broad idea is claimed herein because its novel advantages closely relate to the other features of the present invention. This novel indexing abutment in the embodiment shown is comprised of a lateral deformation of the side Wall of the connector in the form of an indentation extending into the side wall from the outer surface thereof. Referring to FIGURE 1, the upper set of die structures is seen to include a pair of notchjng punches 88 which are so disposed, in this case, that they strike the strip of sheet metal 20 while it is still in flat stock form 42 and produce indentations 94) which, after subsequent formation of the connectors 48, reside in the side walls thereof. These indentations 90 are so formed that a laterally disposed abutment 91 is available for engagement by indexing means. An alternative structure preferable for some applications would be the placing of this indent on the inner bottom surface of the strip of connectors so that, although indexing must then be done from the inner side of the strip, the indent could also serve the functions of partially pre-shearing the connectors one from another and recessing the area to be sheared.

The thickness of the sheet metal stock out of which the connectors are to be made is, of course, dependent on such things as the diameter of the lead wire to be subsequently gripped between the longitudinal end edges of the connector, the hardness, elastic limit, and other charac teristics of this sheet metal stock, the nature of the electrical element, or, possibly, electrical conductor to be gripped therein as well as other variables, such as the size and shape of the crimping dies, which could be adapted to meet specific connector-stock thickness requirements. With quarter or half-hard brass as stock, an electrical element whose circumference is .380 inch, a stock thickness of .023 to .029 inch has been found to be quite satisfactory for use with a soft copper lead wire whose diameter is slightly greater than this thickness. Such brass connectors have a yield point low enough to permit compressive flow of the metal therein during crimping and to thus allow a permanent set to be given to the compressed connectors, and yet are strong enough to securely grip the lead wire and electrical element gripped therein. If the sheet metal used is harder, it could be, accordingly, of less thickness.

Related ot the thickness of the sheet metal used in making the connectors is the problem of insuring the se- 8 cure retention of the lead wire gripped between their longitudinal end edges. In order to insure that this wire is correctly engaged by these edges during the crimping operation (see FIGURES 7 and 8), as well as to subsequently strengthen the assembly, they are provided with thin flanges extending from the outer surface of the side wall of the connector. Referring again to FIGURE 1, the small peening forms 33 are conveniently used to form these flanges a peening punch 92 can be included among the upper die structures 22 so that the side edges of the flat strip 42 are extruded by compression between this punch 92 and the forms 33 to form the flanges 90. After this portion of the strip has been cut and formed into a connector, the flanges 93 are seen to be disposed at the center of the longitudinal end edges 70 of the connector, and is in part an extension of the outer surface of the connector. Although other types of wire-gripping end edge deformations may be used to enhance the security of the retention of the lead wire between the end edges of the connector, these flanges are particularly advantageous as they tend to gather the lead wire into the proper position between the end edges during crimping. Furthermore, the edge recesses 91, left by the metal being peened outward to form the flanges 90, receive extruded portions of the lead wire during the final high-compression stage of the crimping operation, thus serving to key the wire into place (note FIGURES l0 and ll). The flanges themselves, in combination with extrusion of the lead wire, also serve to key the wire against subsequent rotation, as is shown in FIGURE 12. This gripping of the wire is thus made independent of the enclosed element, and enables the pressure on the wire and on the element to be varied independently, as previously discussed.

If thinner and harder material, e.g., steel, is used in the manufacture of connectors which are to be used as described above, it would be distinctly advantageous to so form the longitudinal end edges that they-are efiectively thick enough to grip and retain the lead e. Corrugated edges, for instance, would not only be/Uifectively thick enough, but would enhance a keying? of the wire by permitting extrusion thereof between the corrugations.

The minimization of burrs at the severed ends of the connectors, the minimization of the maximum radial dimens'ion of the connections formed therewith by gripping the lead wire in an opening in the wall of the connector, and the secure keying or rigid gripping of the lead wirethese and other features enhance the subsequent molding of plastic insulating material over the electrical components so formed. For instance, the lead wire is used, advantageously, as a support for the component during such molding-if it is not properly disposed, and securely held, in the component, it may preclude the component being adequately covered with insulation.

I claim:

1. The method of electrically coupling a conductor wire to an elongated electrical component body having a conductive surface by a U-shaped channel including the steps of disposing the conductor wire coaxially along the channel; laying the component body in and along the channel; closing the channel tightly against and in pressure engagement with the conductive surface of the component body; and forcing the longitudinally extending faces, as defined by the stock thickness of the channel, at the ends of the arms of the channel toward abutting relation and against the conductor Wire from opposite sides to grip the conductor wire in electrical engagement.

2. The method of electrically coupling a conductor wire to an elongated electrical component body having a conductive surface by a U-shaped channel including the steps of disposing the conductor wire coaxially along the channel; laying the component in and along the channel; closing the channel tightly against and in pressure engagement with the conductive surface of the component body; forcing the longitudinally extending faces, as defined by the stock thickness of the channel, at the ends of the arms of the channel toward abutting relation and against the conductor wire from opposite sides to grip the conductor wire in electrical engagement; and, while circumferentially confining the channel and conductor wire, compressing the channel beyond its yield point.

3. The method of electrically connecting a conductor wire to a U-shaped channel to be applied on a component body including the steps of laying the component body in and along the channel; disposing the conductor wire coaxially along the channel; bending the arms of the channel inwardly in a direction to form a ferrule embracing the component body and to force the longitudinally extending faces, as defined by the stock thickness of the channel, toward abutting relation and against the conductor wire from opposite sides to grip the conductor wire in electrical engagement; and, While circumferentialiy confining the channel and conductor wire, compressing the channel beyond its yield point.

References Cited in the file of this patent UNITED STATES PATENTS 2,119,292 Rollefson May 31, 1938 2,157,007 Offner May 2, 1939 2,183,109 Sipe Dec. 12, 1939 2,535,013 Freedom Dec. 19, 1950 2,659,871 Berg Nov. 17, 1953 2,778,097 Berg Jan. 22, 1957 2,783,447 Watts n Feb. 26, 1957

Claims (1)

1. THE METHOD OF ELECTRICALLY COUPLING A CONDUCTOR WIRE TO AN ELONGATED ELECTRICAL COMPONENT BODY HAVING A CONDUCTIVE SURFACE BY A U-SHAPED CHANNEL INCLUDING THE STEPS OF DISPOSING THE CONDUCTOR WIRE COAXIALLY ALONG THE CHANNEL; LAYING THE COMPONENT BODY IN AND ALONG THE CHANNEL; CLOSING THE CHANNEL TIGHTLY AGAINST AND IN PRESSURE ENGAGEMENT WITH THE CONDUCTIVE SURFACE OF THE COMPONENT BODY; AND FORCING THE LONGITUDINALLY EXTENDING FACES, AS DEFINED BY THE STOCK THICKNESS OF THE CHANNEL, AT THE ENDS OF THE ARMS OF THE CHANNEL TOWARD ABUTTING RELATION AND AGAINST THE CONDUCTOR WIRE FROM OPPOSITE SIDES TO GRIP THE CONDUCTOR WIRE IN ELECTRICAL ENGAGEMENT.

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