NO782852L - ELECTRICAL CONTACT DEVICE. - Google Patents

Description

This invention relates to the restoration of wire connections and in particular an electrical contact device with an eccentric bore.

US Patent No. 2,264,754 describes an electrical contact device with an eccentric bore comprising a female part with a first bore that communicates with a countersink which is laterally offset relative to the bore, a plug received in the countersink and having an eccentric second bore coaxial with the first bore, means for holding the plug in the recess while allowing relative rotation between the female portion and the plug to clamp an electrical conductor when such is engaged in the bores, a body projecting from the female portion and can be rotated in relation to this, the body being connected to the plug, and abutment surfaces which limit the relative rotation between the plug and the female part to a predetermined angle.

In this known contact device, the plug is eccentrically engaged in the body so that it can be driven in rotation by the body in relation to the female part, the plug being movably mounted in the female part in such a way that its main movement component in relation to the female part is across the axis of the first the bore, the angle of relative rotation between the plug and the female part being limited to only a few degrees by means of the abutment rafts provided within the recess. The construction of the known contact device is such that the angle of the relative rotation cannot be increased particularly even by modification of the abutment rafts.

The problem which the present invention shall solve is to provide an electrical contact device of the type which has an eccentric bore and which is not only more economical to manufacture than the known contact device, but which is capable of producing an efficient and permanent electrical connection with an electrical aluminum conductor, especially an aluminum wire composed of several

threads.

The invention is based on the fact that the plug and the body should form a single unit, as the contact rafts are provided outside this unit, and the permitted angle of rotation between the plug and the body is mainly, for example, 180° so that a cold-welded joint is achieved between the conductor and the contact device.

According to the present invention is therefore a contact device with an eccentric bore as stated in the second paragraph of the description, characterized in that the plug is rigidly connected to the body and the contact surfaces are made up of interacting outer surfaces on the female part and the body, the predetermined angle being such that cold flow is provided between the conductor and the bore walls by mainly torsional shear forces at the transition zone between the first bore and the countersink to provide a cold-welded joint between the conductor and the contact device, the cross-sectional area of the conductor being approximately equal to the cross-sectional area of the bores.

It has been found that these torsional shear forces, when the conductor is a stranded aluminum conductor, cause the alumina coatings on the strands to separate from the underlying metal and cold flow is provided between the strands so that they are welded together into a substantially homogeneous electrically conductive mass. The minimal rotational component of the movement of the plug obtained with the known contact device could not produce any such effect.

Since the contact device according to the present invention comprises only two relatively simple male and female parts and since the contact rafts are formed on the outside of these parts, the device can be produced very economically, for example by mold casting. The fact that the plug and the female part have been rotated in relation to each other to the fully permitted extent can be easily ascertained by visual inspection since the abutment rafts are on the outside.

It is not necessary to use special tools to turn the parts of the contact device in relation to each other.

In order to gain a better understanding of the invention, it must now

reference is made to the drawings as examples of the invention, where:

Figure 1 is a perspective view of the bare end of an electrical cable with a multi-wire electrically conductive core; Figure 2 is a perspective sketch of a two-part electrical contact device with eccentric drilling according to a first embodiment of the invention, attached to the bare end part of the cable core; Figure 3 is a schematic, exploded perspective sketch of the contact device with parts not shown; Figure 4 is a sketch in axial section of the contact device showing the parts of the device assembled before the device is attached to the bare end part of the cable core; Figure 5 is an end view taken in the direction of the arrows v-V in Figure 4; Figure 6 is a sketch of a section taken along lines VI-VI in Figure 7; Figure 7 is a sketch similar to that of Figure 4, but showing the positions of the parts after the contact device is attached to the bare end portion of the cable core; Figure 8 is a perspective view of a two-piece electrical contact device with an eccentric bore according to another embodiment of the invention, attached to the bare end part of the cable core; Figure 9 is an expanded perspective sketch of the contact device in Figure 8; Figure 10 is a sketch in axial section through the device of Figures 8 and 9 showing the parts assembled before the contact device is attached to the bare end part of the cable core; Figure 11 is an end view of Figure 10; Figure 12 is a view taken on lines XII-XII of Figure 13; Figure 13 is a sketch similar to that of Figure 10, but showing the position of the parts after the contact device has been attached to the bare end portion of the core; Figure 14 is a perspective sketch of a part of the contact device in Figures 7 to 13, and Figure 15 is a perspective sketch of the other part of the contact device in Figures 7 to 13, rotated 180° in relation to the position the part is shown in in Figure 9 .

The first embodiment will now be described with reference to figures 1 to 7. The contact device, which is generally designated 2, must be able to be attached to the exposed end part of the electrically conductive core 4 in a cable 6 such as e.g. can be a thick cable of aluminum or copper, e.g. AWG (American Wire Gauge) 6 to AWG 10, which has a multi-wire core as shown, the wires in the core being designated 58.

The contact device 2 comprises a female part 8 and a male part

IO, which parts can conveniently be produced by mold casting. The parts 8 and 10 are preferably made of an aluminum alloy when the core 4 is of aluminium. The female part 8 has a body 12 with sides 14 and 16 facing in opposite directions. A ring tongue 18 extending from the side 16 has a hole 20 for receiving a fastening device (not shown) for fastening the contact device 2 to an electrical busbar (not shown) or another substrate.

A bore 22 for receiving the end part of the core extends into the body 12 from the side 16, the diameter of the bore being substantially equal to and slightly larger than the diameter of the core 4. A plug opening in the form of a recess 24 having a bottom surface 28 extends inwardly from side 14 and communicates with the inner end of bore 22 between sides 14 and 16 of body 12. The axis of recess 24 is offset downwards (as seen in figures 4 and 5) from the axis of bore 22. A rounding 26 is provided around the intersection between the bore 22 and the recess 24 to prevent cutting of the core 4 when the contact device is attached to it, as described below. The mouth of the recess 24 is preferably chamfered outwards as shown at 30 to facilitate assembly of the parts 8 and also 10, as described below. An edge or flange 34 extending from the side 14 of the body 12 in the opposite direction to the tongue 18 and across the entire width of the side 14 has a central curved recess 36 in its inner surface ,70.

The male part 10 has a polygonal body 38, and from its one side 39 extends a cylindrical plug 40 with a circular cross-section. A bore 42 extending from the opposite side 41 of the body 38 and through the entire length of the plug 40 has a diameter which is substantially the same as that of the bore 22, the axis of the bore 42 being shifted upwards (as shown in Figure 4) relative to the axis of the plug 40. The front end, i.e. the free end of the plug 40 has a chamfered outer edge 44 to facilitate assembly of the parts 8 and 10, and an inner rounding 43 to avoid cutting the core 4 when the contact device is attached to the core as described below. A breasting 46 is provided between the plug 40 and the body 38 to avoid such stress concentrations which occur in the core 4 and which would produce cavities when the contact device is attached to the core.

The body 38 is shaped, seen in cross-section, as a regular polygon having sides 50, 52, 54, 56, 58 and 60, the center 66 of the polygon being located to the left (as shown in Figure 5) of the axis 64 of the plug 40 As shown in figure 5, the axis 62 of the bore 42 is vertically aligned with the axis 64 and lies above the center 66 when the parts 8 and 10 are angularly arranged as shown in figure 5.

The parts 8 and 10 are fastened together by means of a split ring 68 received in a circumferential recess 48 in the plug 40, which ring 68 springs or snaps into a circumferential recess 3 2 in the recess 24 when the parts 8 and 10 have been assembled as shown in figure 4..The rounding 43, the chamfered edge 44 and the splitting 68 are not shown in Figure 3.

In the assembled position, the parts 8 and 10 are oriented such that the side 58 of the body 38 lies close to the surface 70 on the edge 34 as shown in Figure 5. It will appear from figure 5 that the parts 8 and 10 are dimensioned so that the corner 57 which is delimited by the sides 56 and 58 is slightly to the right (as shown in figure 5) side of the recess 36 in the surface 70. The parts 8 and 10 are delivered to the user in the assembled form shown in figures 4 and 5 so that the male part

10 can be turned over an angle of mainly 180° until the parts

8 and 10 are arranged in relation to each other as shown in figure 6.

When using the contact device, the end part of the stranded cable 6 is stripped and the bare end part of the core 4 is inserted through the bores 42 and 22 which lie in line, from the side 41 of the body 38. The male part 10 is then turned in relation to the female part 8 using of spanner, for example, through an angle of 180° until the side 52 lies against the surface 70 (figures 6 and 7). The parts 8 and 10 cannot be turned further in relation to each other in the same direction because the corner 51 which is bounded by the sides 52 and 50 lies at a considerable distance to the right (in Figure 6) of the recess 36, and such turning is prevented by the side 52 being towards surface 70.

During the relative rotation of the parts 8 and 10, the channel formed by the aligned bores 22 and 42 is strongly narrowed near the bottom 28 of the recess 24 so that the core is drastically constricted and is thus deformed and compressed in this transition zone between the bores 22 and 42, as cold flow occurs between the core 4 and the walls of the bores 22 and 42. The result of this is that a high-pressure cold-welded electrical connection is produced between the contact device 2 and the core 4.

The roundings 26 and 43 show smooth transition surfaces for the core 4 in the transition zone so that the threads in the core 4 are not cut even if the core 4 comprises very fine aluminum threads.

During the rotation of the male part 10 in relation to the female part

8, the walls of both bores 22 and 42 exert both transverse and rotational or torsional shear forces on the threads 58

in the core 4. Both of these shear modes cause the threads 58 to move relative to. each other. First, the threads are pressed together by the shear forces, but plastic deformation of the threads 58 and cold flow among the threads 58 follow shortly afterwards. The rotational shear and the relative movement of the threads 58 under the forces exerted by the constricting walls of the bores 2 2 and 42 have a scraping or grinding effect on the threads 58 which is transmitted through most of the threads, so that when these threads are aluminum, the brittle aluminum oxide coating (which is an insulator) on these separated from the underlying metal. As the stringing of the core 4 continues, a cold-welded joint is formed between the metal surfaces of neighboring wires and also between the outer wires 58 and the walls of the bores 22 and 42, the wires being welded together into a substantially homogeneous electrically conductive mass. The electrical contact formed by cold flow under the rotational shear forces is far better than that which would be formed by the action of the transverse shear forces alone.

Another significant advantage of the contact device described above is that it consists of only two parts if the split 68 (which is a standard product) is kept out. The contact device can be easily attached to the core 4 using e.g. open spanners by an unskilled worker at the workplace. Furthermore, the electrical connection between the contact device 2 and the core 4 can be inspected visually, as it is easy to see whether the contact device 2 has been properly attached to the core or not.

The contact device can otherwise e.g. constructed as a splicing device to connect the ends of two cable cores, or as a connecting block to connect two or more cable cores at a common point.

The second embodiment of the invention will now be described with reference to figures 8 to 15.

The contact device, which is generally denoted by the reference number 102, comprises a female part 104 and a male part 106, which can also be produced economically using mold casting and is preferably made of an aluminum alloy where the contact device is to be attached to a multi-wire aluminum cable core.

Although the contact device can be made for use with cores of other electrically conductive materials, e.g. cups, the contact device is specially adapted for use with multi-wire aluminum cable cores, and especially aluminum cables with a large cross-section, e.g. AWG 2 or 1.

The female part 104 comprises a mainly rectangular body 112 which is made in one piece with a ring tongue 108 with one hole 110 for receiving a fastening device. The body 112 has two oppositely facing chamfered edges 113 and 113'. A bore 116 which extends from a rear surface 114 of the body 112 is in connection with a recess 118 which extends inwards from the opposite surface 117 (figure 14) of the body 112, the axis of the bore 116 being offset in relation to the axis of the recess 118, which is best visible in figure 10. The transition between the bore 116 and the recess 118 is delimited by a rounded edge 119 which extends completely around the bore 116. A rib 124 extends around the inner periphery of the recess 118 over a angle of 180°. A transverse channel 122 extends from the lower (as seen in Figures 10 and 13) outer surface 123 of the part 104 into the recess 118 to define a transverse surface together with the bottom surface 101 in the recess 118. The channel 122 can be formed by mold casting of the part 104. The inner face 115 of an edge 126 extending from the right (as shown in Figures 9, 10, 13 and 14) lower part of the face 117 is offset radially outward from the peripheral edge of the recess 118. A pin 121 in the wall 120 of the recess 118 furthest from the edge 126 and which is formed after the assembly of the parts 104 and 106, • extends into a groove in the latter part, to hold the parts loosely together as they are first assembled.

The male part 106 consists of a plug 128 formed in one piece with a polygonal, mainly rectangular body 130 which has opposing chamfered edges 132 and 13.2 1 . The part of the body 130 located at the rear or right (as shown in Figures 10 and 13) surface 131 has a cross-section that coincides with the cross-section of the body 112. The body 130 is designed, close to the plug 128, with a curved surface 138 which extends through an arc of 180°, and is surrounded by planar surfaces 140 and 142. The surface 138 is tangential to two adjacent peripheral surfaces 134 and 136 of the body 130. Between the groove 125 and the surface 138 there is formed, on the plug 128, a circular cylindrical surface of a circular cylindrical right portion 146 of the plug 128. The axial outer surface of a semicircular rib 150 extending around the outer end portion 152 of the plug 128 coincides with the free end surface 152 of the plug 128,

the groove 125 being bounded by the axial inner surface of the rib 150 and the axial outer surface of the member 146. A bore 154 which extends throughout the plug 128 and the body 130 has a diameter substantially equal to the diameter of the bore 116, being the axis of the bore 154 is shifted relative to that of the plug.

128 axis. The bore 154 has an inner rounding 103 at the end which lies against the bore 116.

In the first composite position of sections 104 and 106,

as shown in Figures 10 and 11, with the plug 128 engaged in the recess 118 and with the bores 116 and 154 aligned, the common axis 164 (Figures 10 and 11) of the part 146 and the recess 118 is offset from the common axis 162 of the bores 116 and 154. The surface 152 is immediately adjacent to the transition zone between the bore 116, and the depression 118 and the rib 150 are aligned in line with the channel 22. Relative rotation between the parts 104 and 106 can only occur around the axis 164.

When using the contact device, the uncovered end becomes

of the core 4 of the cable 6 inserted into the folded-in bores 116 and 154 from the side 131, and the part 106 is rotated relative to the part 104 in the direction of the arrow A in figure 12 (i.e. clockwise seen in figures 11 and 12) about the axis 164, so that the rib 150 is engaged in the channel 122 to thereby prevent relative axial movement between the parts 104 and 106. Axial forces tending to separate the parts 104 and 106 during their mutual rotation are absorbed by the interaction of the ribs 150 and 124. The curved surface 138 lies immediately adjacent to the surface 115 of the edge 126 of the female part 104, so that the part 106 can rotate (over an arc of 180°) until the surface 134 of the male part 106 abuts against the surface 115 so that the part 106 cannot rotated further in the same direction. It will be apparent from Figure 13 that the core 4 is exposed to both transverse and rotational shear forces as in the first embodiment, and a cold-welded joint is provided between

the core and the contact device by cold flow between the core and the borehole walls. The chamfered edge 113 of the part 104 is now aligned with the chamfered edge 132 of the part 106, and the chamfered edge 113' of the part 104 is aligned with the chamfered edge 132<1>of the part 106, indicating that the core 4 is correctly positioned, i.e. that the parts 104 and 106 are turned 180° in relation to each other so that the bores 116 and 154 are displaced as far apart as possible.

Cutting of the threads 54 is avoided due to the rounds 103 and 119 at the adjacent ends of the bores 116 and 154.

Although the contact devices 2 and 102 are specially designed for use with multi-wire cable cores, they can also be used with cables with a single core.

Claims (10)

1. Electrical contact device with eccentric bore (2 or 102) comprising a female part (8 or 104) with a first bore (22 or 116) which is connected to a recess (24 or 118), which recess is laterally offset from the bore, a plug (40 or 128) received in the recess (24., or 118) and with an eccentric second bore (42 or 154) through this coax-alt with the first bore (22 or 116), means (32, 48, 68 or 121, 125) which hold the plug (40 or 128) in the recess (24 or 118) while allowing relative rotation between the female part (8 or 10 4) and the plug (40 or 128) to lace together an electrical conductor (4) when this is inserted in the bores (22, 116 or 42, 154), a body (38 or' 130) which protrudes from the female part (8 or 10 4) and can be rotated relative to this, the body (38 or 130) is connected to the plug (40 or 128), and abutment surfaces (52, 70 or 115, 134) which can limit the relative rotation between the plug (4 . 134) on the female part (8 or 104) and on the body (38 or 130), the predetermined angle (180 °) being such that cold flow is provided between the conductor (4) and the bore walls by mainly torsional shear forces at the transition zone between the first bore (22 or 106) and the recess (24 or 118) to produce a cold-welded joint between the conductor (4) and the contact device (2 or 102), and where the cross-sectional area of the conductor (4) is approximately equal to the cross-section of the bores (22 or 116, and 42 or 154). 2. Contact device according to claim 1, characterized in that the adjacent edges of the first and second bore (22 and 42 or 116 and 154) are designed with roundings (26 and 43 or 103 and 119). 3. Contact device according to claim 1 or 2, characterized in that one of the contact floats is arranged on a pin (34 or 126) which protrudes from the female part (8 or 104) next to the body (38 or 130), and the the second impact surface is constituted by a side (58 or 136) of the body (38 or 138). 4. Contact device according to claim 3, characterized in that the body (38) is shaped, seen in cross-section, as a regular polygon (50, 52, 54, 58 and 60), that the plug (40) extends from the body ( 38) at a position offset from the center of the polygon, that the pin (34) has a concave recess (36) which faces the body (38) and occupies corners of the polygon during the relative rotation between the plug (40) and the female part (8) ). 5. Contact device according to any of the preceding claims, characterized in that the holding means comprise opposite grooves (32 and 48) in the recess (24) and on the plug (40) and a split ring (48) engaged in the grooves. 6. Contact device according to claim 1, 2 or 3, characterized in that a rib (150) extends around part of the circumference of the plug (128), the recess (24) being designed with a channel (122) which occupies the peripheral rib (150) during the relative rotation between the plug (128) and the female part (104) to prevent relative axial movement therebetween. 7. Contact device according to claim 6, characterized in that the rib (150) is engaged between a shoulder (124) which extends inward into the recess (118), and the bottom surface (101) of the recess (118). 8. Contact device according to claim 6 or 7, characterized in that an internal pin (121) in the recess (118) sticks into it on the side of the rib (150) which is furthest from the base surface (loi) of the recess (118) to prevent extraction of the plug (128) from the recess (118). 9. Contact device according to any of claims 1 to 3, or 6 to 8, characterized in that the contact surfaces comprise a first planar surface (126) on the female part (104) and a second planar surface (134) on the body (130), the second planar surface (134) being adjacent to one end of a curved surface (138) which extends along the circumference of the body (130) and is tangential to the curved surface (138). 10. Contact device according to any of the preceding claims, where the conductor is occupied in the bores and is a multi-stranded aluminum conductor, characterized in that the predetermined angle (180°) is such that cold flow occurs between the threads (58) in the conductor (4) as that they are welded together into an essentially homogeneous electrically conductive mass.