US3280856A

US3280856A - Electrical connectors and means for applying them

Info

Publication number: US3280856A
Application number: US455752A
Authority: US
Inventors: William F Broske; Sr Henry W Demler; Jr William H Knowles; Frederick W Wahl
Original assignee: AMP Inc
Current assignee: TE Connectivity Corp
Priority date: 1962-02-09
Filing date: 1965-05-14
Publication date: 1966-10-25
Anticipated expiration: 1983-10-25

Description

1966 w. F. BROSKE ETAL 3,230,356

ELECTRICAL CONNECTORS AND MEANS FOR APPLYING THEM 5 Sheets-Sheet 1 Original Filed Feb. 9. 62

n INVENTORS WILLIAM F. BPosKE HENEV w. DEMLEE,\5R.

BY wuunM H. KNOWLES 32.

nzzoamcx w. wAHL 4.44 YJAL-A/ Oct. 25, 1966 w. F. BROSKE ETAL 3,280,856

ELECTRICAL CONNECTORS AND MEANS FOR APPLYING THEM 5 Sheets-Sheet 2 Original Filed Feb, 9, 1962 INVENTORS WILUHM F. BPOSKE BY HENRY \lJ. DEMLEK w\LLlPM H. KNOWLES 3E. HZEDEEICK \J. WHH L M, 7% 9 fM Oct. 25, 1966 3,280,856

ELECTRICAL CONNECTORS AND MEANS FOR APPLYING THEM w. F. BROSKE ETAL 5 Sheets-Sheet 5 Original Filed Feb. 9, 62

u mw i m v WB W N DK I K MwHmm emmmfl U m mmum WHM W- Y United States Patent 3 Claims. 01. 140-113) This application constitutes a division of our earlierfiled application, Serial No. 172,183, filed February 9, 1962.

In the art of applying electrical connectors onto conductors, it is frequently necessary to apply such connector intermediate the ends of the conductor. It has also been found necessary to apply connectors of large sizes in areas where auxiliary power is not available, and heavy, cumbersome hydraulic tools cannot be used.

It is an object of this invention to provide a connection between a pair of wires which may be slipped over either or both of the wires at any point on the wire.

It is also an object of this invention to provide a means for securing such wires together, whereby a tight, coldforged connection is made on large-sized wires efiiciently and without the use of auxiliary power. It is also an object of this invention to permit the making of such a connection in areas and under circumstances where the size of the device making the connection must be kept as small as possible.

It is also an object of this invention to provide a method for effecting such a connection which provides a strong electrical joint having high conductivity.

Furthermore, it is an object of this invention to provide a wedge-type connector for joining stranded wires. It has been discovered that the use of this type of connection causes non-uniform, longitudinal movement of the strands which results in separation or splaying of the strands of the wire, known in the trade as bird caging. This phenomenon is to be avoided since it permits debris, moisture, salt spray, atmospheric gases, etc., to lodge in the conductor and promote corrosion. Also, on insulated wires it tends to rupture the insulation. It is also an object of this invention to prevent bird caging by a high rate of forming which effects the connection before bird caging can develop.

Other objects and attainments of the present invention will become apparent to those skilled in the art upon a reading of the following detailed description when taken in conjunction with the drawings in which there are shown and described illustrative embodiments of the invention; it is to be understood, however, that these embodiments are not intended to be exhaustive nor limiting of the invention but are given for purposes of illustration in order that others skilled in the art may fully understand the invention and the principles thereof and the manner of applying it in practical use so that they may modify it in various forms, each as may be best suited to the conditions of a particular use.

In the drawings:

FIGURE 1 is a perspective view of a connector ambodying the principles of this invention;

FIGURE 2 is a planar view of the wedge;

FIGURE 3 is a perspective view of a tool for applying the connector to the conductor;

FIGURE 3A is a sectional view of the tool illustrated in FIGURE 3;

FIGURE 4 is an exploded, perspective view of another connector embodying the principles of this invention;

3,280,856 Patented Oct. 25, 1966 FIGURE 5 is an end view of the device illustrated in FIGURE 4;

FIGURE 6 is a view of the device shown in FIGURE applied to a pair of conductors;

FIGURE 7 is an exploded, perspective view of another connector embodying the principles of this invention;

FIGURE 8 is a perspective view of the device of FIG- URE 7 secured to a pair of conductors;

FIGURE 9 is a device for applying the connector shown in FIGURES 7 and 8 to a pair of conductors;

FIGURE 10 is a stranded conductor illustrating the phenomenon known as bird caging;

FIGURE 11 is another embodiment of a connector employing the principles of this invention;

FIGURE 12 is a view taken through plane 12l2 of FIGURE 11;

FIGURE 13 is an exploded perspective view of yet another embodiment of a connector employing the principles of this invention; and

FIGURE 14 is a view similar to FIGURE 13 showing the connector assembled onto a plurality of conductors.

As shown in FIGURE 1, a preferred embodiment includes a two-piece assembly comprised of a tubular outer shell 10, which in the preferment is substantially C- shaped in cross-section. The shell 10 has a straight back portion 11, and an -I-shaped inner wedge member 12. The C-shaped shell tapers from a section 14 at one end, which has a greater cross-sectional periphery than the other end 16.

The wedge member 12 is I-shaped and has a pair of concave,

arcuate surfaces

18 and 20 on opposite ends thereof. The wedge member is tapered from one end to the other in the same manner as the outside shell. This may be accomplished by making these straight originally, and compressing one end thereof to form a bulge 21 in the I-shaped section. Making the section I-shaped permits the forming of the bulge section more easily. Thus the taper on the inside surface of the C-shaped member corresponds with the taper on the

arcuate members

18 and 20.

As shown in FIGURE 3A, conductor 22 is disposed between the surface 18 and the inside bight of the C-shaped member 10, and a second conductor 24 is disposed between the arcuate surface 20 on the opposite side of the C-shaped member 10.

With the conductors in this position, the wedge 12 is driven longitudinally relative to the C-shaped member until it is coextensive therewith, as shown in FIGURE 1.

The embodiment shown in FIGURES 4-6 is similar to that shown in FIGURES 1 and 2. A tubular mem ber comprised of a C-shaped tapered shell 10' is adapted to receive an I-shaped tapered wedge member 12' with a pair of opposite arcuate surfaces 18' and 20'. The distribution from the prior embodiment is that the back portion 11' of the shell 10' is arcuate rather than straight.

Again a pair of conductors 22' and 24 (FIGURE 6) are adapted to be inserted between the surfaces 18 and 20' respectively, and the corresponding inner surfaces of the shell 10' and the wedge are driven in place to effect the crimped connection by reducing the radius of the arcuate section 11.

The advantage of this construction is that a considerably larger range of wire sizes may be accommodated without changing shell 10' or wedge 12'. Since the shell 10' is capable of expanding through flattening the are 11', the diameter of the wire controls their expansion. Furthermore, the shell 10 has a tendency to return to its original shape which results in a residual pressure being applied to the conductor after the connection is made.

position; however,

A tool suitable for applying either of the previously described connectors is illustrated in FIGURES 3 and 3A. A head member 50 is pivoted to a cylindrical body member 52 by a pin 54. A cap 88 is threadedly secured to the other end of the body member 52.

Referring again to the head member 50, a connectorsupporting surface 58 has a flange 60 at one end thereof. Also secured to this surface is a pin 62 which projects from the head member to form a latch.

The body member has an arm 64 extending therefrom and the pin 54 pivots the head 50 to the body member 52. The opposite side of the body member has a second pivot pin 66 which pivotally secures a hook 68 thereto. The hook is spring-loaded in a counterclockwise direction as seen in FIGURE 3A. It is observed that the hook 68 cooperates with the pin 62 to latch the head in closed during the locking cycle, the hook 68 can be depressed against the action of a spring 69 to unlatch the head member.

The body member 52 also has a shelf 70 which is coextensive with the inner surface of the flange 60. As shown in FIGURE 3A, the flange 60 and the pin 62 cooperate to retain the outer shell of the connector therebetween.

The body member 52 is essentially cylindrical and has a ram 72 longitudinally disposed therein. The free end of the ram projects from the cylinder at the base of the arm 64. As shown in FIGURE 3A, the free end of the ram 72 is adapted to bear against the

wedge

12 or 12 to drive it longitudinally into the shell or 10 and secure the conductors thereto.

A piston 74 is secured to the ram 72 and is adapted to ride in a chamber 76 within the cylindrical body member 52. One end of the ram 72 is secured to the piston, and at the other side of the piston a firing ram 78 is attache-d. The outer surface of the body member 52 has ,a collar 80 secured thereto. A tubular member 82 is slidable within the cylinder 52 and has a spline 84 disposed between the end of the cylinder 52 and the inner cylinder 86 on the collar 80. The spacing between the shoulder '86 and the end of the cylinder 52 permits longitudinal motion of the tubular member 82. Also, as shown in FIGURE 3A, the firing ram 78 projects down into the tubular member 82.

A cap 88 is secured to the free end of the tubular member 82. A plastic cartridge containing explosive material (described in Patent No. 3,007,409) may be inserted into the tubular member 82 with the firing piston projecting into the cartridge. The outer end of the tubular member 82 supports the head of the cartridge, and a prong 90 on the inner end of the head permits release of escaped gases (described in application Serial No. 164,756).

OPERATION When it is desired to secure a wedge-type connector, .as shown in FIGURES l and 4, to a pair of conductors, the hook 68 is released from the pin 62 and the head .50 is pivoted into open position. The conductor shell is inserted into the head surface 58 with the conductors in.- serted into the appropriate positions in the shell. The wedge 12 placed on the body member 52 in juxtaposition to the ram 72. The head member 50 is then rotated to its closed position and the hook 68 snaps closed over the pin 62. In this relationship, the wedge projects slightly into the connector shell. The cap 88 is unthreaded from the tubular member 82 and .a cartridge inserted into position. The cap is then threaded in place to secure the cartridge in firing position. A sharp blow is then applied to the cap 88 which causes it to move upwardly detonating the cartridge against the firing ram 78. Explosion of the powder charge drives the ram 78 forward.- ly and actuates the driving ram 72 against the wedge 12. This drives the wedge into connector-forming position within the C-shaped shell 10. The tool may then be released and the cartridge removed from further operation.

Directing attention to FIGURES 7 and 8 disclosing another embodiment of a connector employing the principles of this invention, the device comprises a tubular member which is substantially C-shaped, and a pair of

wedge members

112 and 112 which are designed to fit within the center section 113 of the C-shaped member 110. The internal section 113 of the C-shaped member 110 has a pair of opposed, internal

arcuate surfaces

114 and 116 formed by the bight of the C-shaped portion.

The wedge member 112 has an upper arcuate surface 118, and the other wedge member 112 has a similar arcuate lower surface 120. The surface of the wedge member 112, which is opposite to the arcuate surface 118, is a tapered planar surface 122. The other wedge member 112 also has a similar planar surface 124 that is tapered in the opposite direction from the surface 122. The two

Wedge members

112 and 112 may be lightly bonded together, as shown in FIGURE 7, for ease in assembly. Any suitable adhesive may be used that will retain them in this position without interfering with lateral motion of the wedges.

The connector of FIGURE 7 may be assembled with the

wedges

112 and 112 disposed centrally of the C- shaped member in the opening 113. With the wedges in extended position, a pair of conductors C and C may be inserted in the upper and

lower bight portions

114 and 116 of the connector 110. The

wedges

112 and 112 are inserted between the conductors C and C. A suitable device (such as shown in FIGURE 9) may be used to drive the

Wedges

112 and 112 laterally toward each other, causing the planar surfaces 124 and 122 to drive the

arcuate surfaces

118 and 120 against the corresponding

surfaces

114 and 116 in the shell 110. This causes the conductors C and C to be wedged tightly within the shell 110 and retained therein by the

wedge members

112 and 112.

A tool for making the connections of FIGURE 8 is illustrated in FIGURE 9, and includes a head member, generally designated 150, and a body member designated at 152. The structure for actuating the tool is identical with the device set forth and described in FIGURES 3 and 3A, and the description will not be repeated. The head of the tool has a connector-receiving surface 158 with a flange 160 projecting from one end thereof. An opposing shelf 162 cooperates with the flange 160 to retain the connector 110 therein. v

The body member 152 may be slotted or comprise a pair of plates which are bolted together, but spaced from each other to retain linkage members. A pair of driving members 163 and 164 are pivoted, respectively, at 166 and 168 to the body member 152. The member 163 is adapted to bear against the free end of wedge member 112, while the member 164 is similarly adapted to bear against the free end of the wedge member 112. Each of these members 162 and 164 are secured to a

link

170 and 172 respectively through pins 174 and 176. The links 1170 and 172 are commonly pivoted at to a ram 182 which is associated with the actuating means in the same manner as the embodiment shown in FIGURES ,3 and 3A, The pin 180 is adapted to slide longitudinally in an aperture 184. Lateral movement of the pin 180 in the aperture 184 causes the

links

170 and 172 to rotate the driving means 163 and 164 about pivot pins 166 and 168.

When it is desired to make a connection of the type shown in FIGURES 7 and 8 with the tool of FIGURE 9, the conductors C and C are inserted within the shell 110 adjacent the

inner surfaces

114 and 116. The wedges 112 and 112' are inserted within the conductors and the assembly is then placed in the tool, as shown in FIGURE 9, with the flange 16.0 and opposed surface 162 retaining the shell 110 in place.

A cartridge is inserted in the tool and exploded in the method described above with regard .to FIGURES 3 and 3A. Longitudinal movement upwardly of the ram 182 drives the pin 180 upwardly, causing the

links

170 and 172 to rotate the actuating members 163 and 164. The

member 163 rotates clockwise, as shown in FIGURE 9, while the actuating means 164 rotates counter-clockwise. The actuating means 163 bears against the wedge 112 and drives it inwardly. Concurrently, the actuating means 164 operates against the free end of the wedge 112 and also drives it inwardly. The two wedges, 112 and 112', move inwardly, riding on their inclined planes, and are disposed laterally to the longitudinal axis of the connectors C and C to tightly grip the conductors within the shell 110. As shown in FIGURE 10, a stranded conductor C comprises a plurality of strands S of conductive material, such as copper or aluminum. At one end of the conductor, designated at 200, the strands are tightly braided together in the desired fashion. When a connection is made with one end of the conductor, slow relative motion of a wedgetype member across the strands causes the strands to rotate relative to the fixed end, thus opening the strands as shown in the central section 202. This is the phenomenon known as bird caging, described above, which is detrimental to proper use of a stranded conductor. In presentday usage when such bird caging occurs, it is common practice to fill the space between the strands with epoxy resin or some other suitable material to prevent entrance of moisture, corrosion, and other corrosion-inducing materials. Applicants have discovered that the use of an explosively-driven device, such as shown in FIGURES 3, 3A and 9, used in combination with a wedge-type connector causes practically instantaneous reforming of the conductor within the wedge-shaped member so that bird caging is virtually eliminated.

The embodiment illustrated in FIGURES 11 and 12 employs the same principles as the alternative embodiments shown in FIGURES 1, 4 and 7. The particular application is known as a dead end splice. The connector portion 300 of the splice is substantially C-shaped as shown in FIGURE 12. As in the other embodiments, a tubular outer shell 310 has a straight back portion adapted to receive a wedge member 312. The shell tapers from a larger cross-sectional portion at one end 314 to the smaller end 316.

The wedge 312 has a concave, arcuate surface 318 on one side which cooperates with a bight of the tubular member 310 (FIGURE 12). The opposed surface 320 of the Wedge 312 is convex and cooperates with the opposed bight of the shell 310.

The remainder of the assembly illustrated in FIGURE 11 is standard, and is included in the drawings for clarity. The connector portion 300 may be secured to any standard, dead-end splice 330, which is secured to a pole P by links 332 through insulation 334.

A conductor 322 may be secured in the connector 310 in the manner described in the other embodiments. The convex arcuate surface 320 of the wedge 312 cooperates with the corresponding bight of the tubular shell 310 to lock the wedge in the shell, rather than to secure a second conductor therein, as depicted in the previously-described embodiments.

The embodiment illustrated in FIGURES 13 and 14 is also similar to the various previously-described devices. In this form, the shell 410 is continuous rather than being C-shaped. The wedge 412 is identical with the wedge 12 shown in FIGURE 1, described above. A pair of

conductors

422 and 424 may be spliced in this same manner, as described in connection with the embodiment of FIGURE 1. The connector of FIGURES 13 and 14 may be used in applications where it is possible to thread the conductor into the connector. The C-shaped connectors may be used where it is necessary to tap into an intermediate portion of a conductor. Either the C-shaped shell or the continuous shell may be used with the various embodiments within the intent of the invention.

Changes in construction will occur to those skilled in the art and various apparently different modifications and embodiments may be made without departing from the scope of the invention. The matter set forth in the foregoing description and accompanying drawings is offered by Way of illustration only. The actual scope of the invention is intended to be defined in the following claims when viewed in their proper perspective against the prior art.

We claim:

1. A device for applying an electrical connector to a conductor, comprising a head member, means in said head member for engaging a connector, a body member secured to said head member, means associated with said body member for retaining an explosive charge therein, and a lost motion connection between the body member and the means for retaining the explosive charge.

2. A device for applying an electrical connector to a conductor, comprising a head member, means in said head member for engaging a connector, a body member secured to said head member, means associated with said body member for retaining an explosive charge therein, a ram member in said body member with one end of the tubular member in proximity to the explosive charge and the other end of the tubular member in proximity to the electrical connector, and a lost motion connection between the body member and the means .for retaining the explosive charge.

3. The device of claim 2 including a pair of pivotal members adapted to effect the electrical connection between the connector and the conductor.

References Cited by the Examiner UNITED STATES PATENTS 1,801,277 4/ 1931 Kelly 339247 2,038,913 4/1936 Temple -113 2,106,724 2/ 1938 Cope 339247 2,801,400 7/ 1957 Noirclerc 339247 2,930,113 3/1960 Greco 29155.55 2,968,043 1/ 1961 Demler 1--215 2,980,991 4/1961 Frank 29203 3,010,184 11/1961 Forney 29155.55 3,045,336 7/ 1962 Northrop et al. 29203 3,060,437 10/ 1962 Henning et al. 1-44.5 3,065,449 11/1962 Matthysse et al 339247 CHARLES W. LANHAM, Primary Examiner.

JOSEPH D. SEERS, Examiner.

P. TEITELBAUM, W. H. JUST, Assistant Examiners.

Claims

1. A DEVICE FOR APPLYING AN ELECTRICAL CONNECTOR TO A CONDUCTOR, COMPRISING A HEAD MEMBER, MEANS IN SAID HEAD MEMBER FOR ENGAGING A CONNECTOR, A BODY MEMBER SECURED TO SAID HEAD MEMBER, MEANS ASSOCIATED WITH SAID BODY MEMEBR FOR RETAINING AN EXPLOSIVE CHARGE THEREIN,