[0001] Electrical busbars, such as elongated rectangular flat conductive bus bars, have
long been utilized in the electrical distribution industry to conduct electricity.
Two electrical busbars have been conventionally connected together by drilling or
otherwise forming holes through the two electrical busbars and coupling the busbars
together utilizing bolts disposed through the holes.
DE 298 16 627 U1 discloses clamping members consisting of rectangular metal plates which run on both
sides of a bus bar with spacing relative to its surface. Contact pieces protrude from
the clamping members in the direction of the bus bar to attach the clamping members
to the bus bar. The drilling process, however, is a labor intensive and time consuming
task. Additionally, the need for bolts adds cost and labor for installation.
[0002] DE 4124066 A1 describes an electric lighting system with a conducting bar to clamp a lampholder.
The conducting bar is clamped by two clamping members adjoining the conducting bar
at two sides within a gap between the two clamping members which are fixed by bolts.
[0003] Accordingly, the inventors herein have recognized a need for improved electrical
connectors.
[0004] The present invention provides an electrical connector as defined in claim 1.
[0005] An electrical connector in accordance with an exemplary embodiment is provided. The
electrical connector includes a first mounting portion. The electrical connector further
includes a first clamping portion coupled to the first mounting portion. The first
clamping portion has a first coupling tab and a second coupling tab. The first coupling
tab extends from the first mounting portion in a first direction. The first coupling
tab has first and second apertures extending therethrough. The second coupling tab
extends from the first mounting portion in the first direction. The first and second
coupling tabs define a first gap. The second coupling tab has third and fourth apertures
extending there through. The third and fourth apertures are aligned with the first
and second apertures, respectively. The first and third apertures are configured to
receive a first fastener. The second and fourth apertures are configured to receive
a second fastener. The first gap is sized to receive a first busbar. The first and
second coupling tabs are configured to form an electrical connection with the first
busbar in the first gap.
includes cooling the extruded portion utilizing a cooling device. The method further
includes cutting the extruded portion into the plurality of connector portions utilizing
a cutting device. Each connector portion has a mounting portion and a clamping portion.
Each clamping portion has first and second coupling tabs that extend from a respective
mounting portion.
[0006] These and other advantages and features will become more apparent from the following
description taken in conjunction with the drawings.
[0007] The subject matter, which is regarded as the invention, is particularly pointed out
and distinctly claimed in the claims at the conclusion of the specification. The foregoing
and other features, and advantages of the invention are apparent from the following
detailed description taken in conjunction with the accompanying drawings in which:
FIG. 1 is a schematic of an electrical circuit having an electrical connector in accordance
with an exemplary embodiment;
FIG. 2 is a schematic of a first connector portion of the electrical connector of
FIG. 1;
FIG. 3 is another schematic of the first connector portion of the electrical connector
of FIG. 1;
FIG. 4 is a side view of the first connector portion of FIG. 3;
FIG. 5 is a cross-sectional view of the first connector portion of FIG. 3;
FIG. 6 is a schematic of a second connector portion of the electrical connector of
FIG. 1;
FIG. 7 is a side view of the second connector portion of FIG. 6;
FIG. 8 is a cross-sectional view of the second connector portion of FIG. 6;
FIGS. 9 and 10 are a flowchart of a method for coupling an electrical connector to
a busbar in accordance with another exemplary embodiment;
FIG. 11 is a schematic of an electrical circuit having an electrical connector in
accordance with an exemplary embodiment;
FIG. 12 is a schematic of the electrical connector of FIG. 11 in accordance with an
exemplary embodiment;
FIG. 13 is a cross-sectional schematic of an embodiment of the electrical connector
of FIG. 11;
FIG. 13A is a cross-sectional schematic of an embodiment of the electrical connector
of FIG. 11;
FIG. 14 is a schematic of an embodiment of the electrical connector of FIG. 11 in
a flexed configuration disposed on first and second busbars;
FIG. 15 is a cross-sectional schematic of an embodiment of the electrical connector
and the first and second busbars of FIG. 14;
FIG. 16 is a schematic of an embodiment of the electrical connector of FIG. 11 configuration
and disposed on the first and second busbars;
FIG. 17 is a cross-sectional schematic of the electrical connector and the first and
second busbars of FIG. 16;
FIG. 18 is a flowchart of a method for coupling an electrical connector to first and
second busbars in accordance with another exemplary embodiment;
FIG. 19 is a block diagram of a system for manufacturing a plurality of connector
portions of electrical connectors in accordance with another exemplary embodiment;
FIG. 20 is a schematic of an extruding die utilized in the system of FIG. 19 and an
extruded portion exiting the extruding die;
FIG. 21 is an enlarged schematic of a portion of the extruded portion of FIG. 20;
FIG. 22 is a schematic of a connector portion cut from the extruded portion of FIG.
20 prior to the apertures being drilled;
FIG. 23 is a schematic of the connector portion of FIG. 22 having apertures drilled
therein;
FIG. 24 is a schematic of the extruding die utilized in the system of FIG. 19;
FIG. 25 is another schematic of the extruding die utilized in the system of FIG. 19;
FIG. 26 is a flowchart of a method for manufacturing a plurality of connector portions
of electrical connectors in accordance with another exemplary embodiment; and
FIG. 27 is an enlarged schematic of the electrical connector of FIG. 1.
[0008] The detailed description explains embodiments of the invention, together with advantages
and features, by way of example with reference to the drawings.
[0009] Referring to FIGS. 1-3, an electrical circuit 10 having a first busbar 20, a second
busbar 22, and an electrical connector 30 in accordance with an exemplary embodiment
is illustrated. An advantage of the electrical connector 30 is that the connector
30 is coupled to the first busbar 20 and the second busbar 22 without drilling holes
in the busbars 20, 22.
[0010] The first busbar 20 and the second busbar 22 are each constructed of an electrically
conductive material for conducting electricity therethrough. In one exemplary embodiment,
the first busbar 20 and the second busbar 22 are constructed of copper.
[0011] The electrical connector 30 includes a first connector portion 31, a second connector
portion 32, and fasteners such as bolts 33, 34, 35, 36 for example. The first connector
portion 31 is coupled to the second connector portion 32 utilizing the bolts 33, 34,
35, 36.
[0012] Referring to FIGS. 1, 3-5, and 27, the first connector portion 31 is configured to
be coupled to the second connector portion 32 and to the busbar 20. The first connector
portion 31 includes a mounting portion 40; a clamping portion 41 having coupling tabs
42, 44; fasteners such as bolts 60, 62; and nuts 64, 66. The mounting portion 40 may
be block-shaped and includes apertures 80, 82, 84, 86 extending therein. In one exemplary
embodiment, the block-shaped mounting portion 40 is parallelepiped shaped. The mounting
portion 40 is constructed of an electrically conductive material. In one exemplary
embodiment, the mounting portion 40 is constructed of copper. Of course, in an alternative
embodiment, the mounting portion 40 could be constructed of another electrically conductive
material suitable for a purpose disclosed herein.
[0013] Referring to FIGS. 3 and 5, the clamping portion 41 having coupling tabs 42, 44 is
configured to hold the busbar 20 between the coupling tabs 42, 44. The coupling tab
42 extends from the mounting portion 40 in a first direction. The coupling tab 42
has apertures 100, 102 extending therethrough. The coupling tab 44 extends from the
mounting portion 40 in the first direction such that a gap 50 is formed between the
coupling tabs 42, 44. The gap 50 has a size sufficient to receive an end portion of
the busbar 20 therein. The coupling tab 44 has apertures 110, 112 extending therethrough.
The apertures 110, 112 in the coupling tab 44 are aligned with the apertures 100,
102 respectively in the coupling tab 42. The coupling tabs 42, 44 have grooves 121,
123, respectively, disposed proximate to the mounting portion 40, wherein the coupling
tabs 42, 44 are bendable proximate the grooves 121, 123, respectively, toward one
another. The coupling tabs 42, 44 are each constructed of an electrically conductive
material. In one exemplary embodiment, coupling tabs 42, 44 are constructed of copper.
Of course, in an alternative embodiment, the coupling tabs 42, 44 could each be constructed
of another electrically conductive material suitable for a purpose disclosed herein.
[0014] The bolt 60 is configured to be disposed through the apertures 100, 110 and is coupled
to the nut 64. The bolt 62 is configured to be disposed through the apertures 102,
112 and is coupled to the nut 66. When bolts 60, 62 are tightened within the nuts
64, 66, respectively, the coupling tabs 42, 44 are urged towards one another such
that the coupling tabs 42, 44 are fixedly clamped against the first busbar 20 disposed
through the gap 50 between the coupling tabs 42, 44. Also, the mounting portion 40
is electrically coupled to the first busbar 20 via the coupling tabs 42, 44.
[0015] Referring to FIGS. 6-9, the second connector portion 32 is configured to be coupled
to the first connector portion 31 and to the busbar 22. The second connector portion
32 includes a mounting portion 240; a clamping portion 241 having coupling tabs 242,
244; fasteners such as bolts 260, 262; and nuts 264, 266. The mounting portion 240
may be block-shaped and includes apertures 280, 282, 284, 286 extending therein. In
one exemplary embodiment, the block-shaped mounting portion 240 is parallelepiped
shaped. The mounting portion 240 is constructed of an electrically conductive material.
In one exemplary embodiment, the mounting portion 240 is constructed of copper. Of
course, in an alternative embodiment, the mounting portion 240 could be constructed
of another electrically conductive material suitable for a purpose disclosed herein.
[0016] The clamping portion 241 having coupling tabs 242, 244 is configured to hold the
busbar 22 between the coupling tabs 242, 244. The coupling tab 242 extends from the
mounting portion 240 in a first direction. The coupling tab 242 has apertures 300,
302 extending therethrough. The coupling tab 244 extends from the mounting portion
240 in the first direction such that a gap 250 is formed between the coupling tabs
242, 244. The gap 250 has a size sufficient to receive the busbar 22 therein. The
coupling tab 244 has apertures 310, 312 extending therethrough. The apertures 310,
312 in the coupling tab 244 are aligned with the apertures 300, 302 respectively in
the coupling tab 242. The coupling tabs 242, 244 have grooves 321, 323, respectively,
disposed proximate to the mounting portion 240, wherein the coupling tabs 242, 244
are bendable proximate the grooves 321, 323, respectively, toward one another. The
coupling tabs 242, 244 are each constructed of an electrically conductive material.
In one exemplary embodiment, coupling tabs 242, 244 are constructed of copper. Of
course, in an alternative embodiment, the coupling tabs 242, 244 could each be constructed
of another electrically conductive material suitable for a purpose disclosed herein.
[0017] The bolt 260 is configured to be disposed through the apertures 300, 310 and is coupled
to the nut 264. The bolt 262 is configured to be disposed through the apertures 302,
312 and is coupled to the nut 266. When bolts 260, 262 are tightened within the nuts
264, 266, respectively, the coupling tabs 242, 244 are urged towards one another such
that the coupling tabs 242, 244 are fixedly clamped against the second busbar 22 disposed
through the gap 250 between the coupling tabs 242, 244. Also, the mounting portion
240 is electrically coupled to the second busbar 22 via the coupling tabs 242, 244.
[0018] Referring to FIGS. 9 and 10, a flowchart of a method for coupling the electrical
connector 30 to busbars 20, 22 in accordance with another exemplary embodiment will
be explained.
[0019] At step 350, the user provides the first connector portion 31 having a mounting portion
40; the clamping portion 41 having coupling tabs 42, 44; bolts 60, 62; and nuts 64,
66. The coupling tab 42 extends from the mounting portion 40 in a first direction.
The coupling tab 42 has apertures 100, 102 extending therethrough. The coupling tab
44 extends from the mounting portion 40 in the first direction such that the gap 50
is formed between the coupling tabs 42, 44. The coupling tab 44 has apertures 110,
112 extending therethrough. The apertures 110, 112 are aligned with the apertures
100, 102, respectively. The bolt 60 is disposed through the apertures 100, 110 and
is coupled to the nut 64. The bolt 62 is disposed through the apertures 102, 112 and
is coupled to the nut 66.
[0020] At step 352, the user provides the second connector portion 32 having a mounting
portion 240; a clamping portion 241 having coupling tabs 242, 244; bolts 260, 262;
and nuts 264, 266. The coupling tab 242 extends from the mounting portion 240 in a
first direction. The coupling tab 242 has apertures 300, 302 extending therethrough.
The coupling tab 244 extends from the mounting portion 240 in the first direction
such that the gap 250 is formed between the coupling tabs 242, 244. The coupling tab
244 has apertures 310, 312 extending therethrough. The apertures 310, 312 are aligned
with the apertures 300, 302, respectively. The bolt 260 is disposed through the apertures
300, 310 and it is coupled to the nut 264. The bolt 262 is disposed through the apertures
302, 312 and is coupled to the nut 266.
[0021] To form the electrical connector 30 as a combination of the first connector portion
31 and the second connector portion 32, the mounting portion 240 can be coupled to
the mounting portion 40 or formed as a unitary body. The coupling tabs 242 and 244
extend from the mounting portion 240 in an opposite direction relative to the direction
in which the coupling tabs 42 and 44 extend from the mounting portion 40. The mounting
portion 40 is a first mounting portion, and the mounting portion 240 is a second mounting
portion. The clamping portion 41 is a first clamping portion, and the clamping portion
241 is a second clamping portion. The coupling tabs 42, 44, 242, 244 are first, second,
third, and fourth coupling tabs, respectively. The apertures 100, 102, 110, 112, 300,
302, 310, 312 are first, second, third, fourth, fifth, sixth, seventh, and eighth
apertures, respectively. The gap 50 is a first gap, and the gap 250 is a second gap.
The bolts 60, 62, 260, 262 are first, second, third, and fourth fasteners, respectively.
[0022] At step 354, the user inserts the first busbar 20 within the gap 50 such that the
first busbar 20 is disposed between the coupling tabs 42, 44 and further disposed
between the bolts 60, 62.
[0023] At step 356, the user rotates the bolts 60, 62 within the nuts 64, 66, respectively,
such that the coupling tabs 42, 44 are fixedly clamped against the first busbar 20.
Also, the mounting portion 40 is electrically coupled to the first busbar 20.
[0024] At step 358, the user inserts the second busbar 22 within the gap 250 such that the
second busbar 22 is disposed between the coupling tabs 242, 244 and is further disposed
between the bolts 260, 262.
[0025] At step 360, the user rotates the bolts 260, 262 within the nuts 264, 266, respectively,
such that the coupling tabs 242, 244 are fixedly clamped against the second busbar
22, and the mounting portion 240 is electrically coupled to the second busbar 22.
[0026] Referring to FIGS. 19, 20, 24 and 25, a system 700 for manufacturing a plurality
of connector portions of electrical connectors in accordance with another exemplary
embodiment will now be explained. The system 700 includes a melting device 710, an
extruding device 720, a first conveyor device 730, a cooling device 740, a second
conveyor device 750, a cutting device 760, and a drilling device 770.
[0027] The melting device 710 is configured to melt a metal to form a liquid metal 712.
In one exemplary embodiment, the liquid metal 712 is liquid copper.
[0028] The extruding device 720 is configured to receive the liquid metal 712 from the melting
device 710 and to move the liquid metal 712 through an extruding die 724 within the
extruding device 720 to form an extruded portion 726. The extruded portion 726 has
a cross-sectional profile corresponding to a connector portion. The extruding die
724 is constructed of plates 780, 782, 784, 786, 788, 790 coupled together. The extruding
die 724 has an inlet aperture 820 and an outlet aperture 824. The outlet aperture
824 has a profile corresponding to a connector portion such that when the liquid metal
712 exits the outlet aperture 824, the extruded portion 726 has a cross-sectional
profile corresponding to a connector portion.
[0029] The first conveyor device 730 is configured to move the extruded portion 726 exiting
the extruding device 720 from the extruding device 720 to the cooling device 740.
[0030] The cooling device 740 is configured to cool the extruded portion 726 such that the
extruded portion 726 is solidified. In one exemplary embodiment, the cooling device
740 applies a liquid on the extruded portion 726 to cool the extruded portion 726.
[0031] The second conveyor device 750 is configured to move the extruded portion 726 from
the cooling device 740 to the cutting device 760.
[0032] Referring to FIGS. 19, 22 and 23, the cutting device 760 cuts the extruded portion
760 into the plurality of connector portions 31. Each connector portion 31 has a mounting
portion 40 and a clamping portion 41. Each clamping portion 41 has first and second
coupling tabs 42, 44 that extend from a respective mounting portion 40.
[0033] Referring to FIGS. 5 and 19, the drilling device 770 drills apertures 100, 102 in
the coupling tab 42 and apertures 110, 112 in the coupling tab 44. The apertures 100,
110 are aligned with one another, and the apertures 102, 112 are aligned with one
another.
[0034] Referring to FIGS. 5, 19 and 23, the drilling device 770 drills the apertures 80,
82, 84, 86 through each mounting portion 40 of each connector portion 31.
[0035] Referring to FIGS. 5, 19, 20, 24 and 25, a flowchart of a method for manufacturing
a plurality of connector portions of electrical connectors in accordance with another
exemplary embodiment will now be explained.
[0036] At step 900, the melting device 710 melts a metal to form a liquid metal 712 and
the extruding device 720 moves the liquid metal 712 through the extruding die 720
to form the extruded portion 726 having a cross-sectional profile corresponding to
a connector portion 31.
[0037] At step 902, the first conveyor device 730 moves the extruded portion 726 to the
cooling device 740.
[0038] At step 904, the cooling device 740 cools the extruded portion 726.
[0039] At step 906, the second conveyor device 750 moves the extruded portion 726 from the
cooling device 740 to the cutting device 760.
[0040] At step 908, the cutting device760 cuts the extruded portion 726 into the plurality
of connector portions 31. Each connector portion 31 has a mounting portion 40 and
a clamping portion 41. Each clamping portion 41 has first and second coupling tabs
42, 44 that extend from a respective mounting portion 40.
[0041] At step 910, the drilling device 770 drills at least first and second apertures 100,
110 in the first and second coupling tabs 42, 44, respectively, of each clamping portion
41, that are aligned with one another.
[0042] At step 912, the drilling device 770 drills at least one aperture 80 through each
mounting portion 40 of each connector portion 31.
[0043] Referring to FIGS. 11 and 15, an electrical circuit 400 in accordance with an exemplary
embodiment is provided. The electrical circuit 400 includes a first busbar 420 having
a top surface 420A and a bottom surface 420B; a second busbar 422 having a top surface
422A and a bottom surface 422B; a third busbar 424; an electrical connector 430; and
at least one fastener 432 such as a bolt, and a corresponding nut (not shown). The
first busbar 420, the second busbar 422, and the third busbar 424 are each constructed
of electrically conductive material for conducting electricity therethrough. In one
exemplary embodiment, the first busbar 420, the second busbar 422, and the third busbar
424 are constructed of copper.
[0044] In an embodiment, the first busbar 420 is coupled at a first end to the second bus
bar 422 by the electrical connector 430, and coupled at a second end to third busbar
424 via fasteners, such as bolts. In another embodiment, the first busbar 420 is coupled
at a first end to third bus bar 424 by a first electrical connector 430, and coupled
at a second end to first busbar 420 via a second electrical connector 430 (not shown).
[0045] In an embodiment the electrical connector 430 is configured to electrically couple
the first busbar 420 extending in a first direction "X", and the second busbar 422
extending in a second direction "Y". In an embodiment, the first and second directions
X, Y are substantially orthogonal. An advantage of the electrical connector 430 is
that the connector 430 can be coupled to the second busbar 422 without the need to
form holes in the busbar 422, such as by drilling.
[0046] Referring to FIGS. 11-13A, and in an embodiment, the electrical connector 430 includes
a first mounting portion 450, a clamping portion 452, and a second mounting portion
454. The electrical connector 430 is constructed of an electrically conductive material
for conducting electricity therethrough. In one exemplary embodiment, the electrical
connector 430 is constructed of copper. In alternative embodiments, the electrical
connector 430 may be constructed of any desired electrically conductive material suitable
for a purpose disclosed herein.
[0047] The first mounting portion 450 comprises a receiving portion 460. The receiving portion
460 is sized and disposed to receive an end portion 461 of the first busbar 420. In
one embodiment, the receiving portion 460 defines a first aperture 460A extending
therethrough sized and disposed to receive the end portion 461 of the first busbar
420 therethrough (Fig. 13). In another embodiment, the receiving portion 460 defines
a slot 460B sized and disposed to receive the end portion 461 of the first busbar
420 therein (Fig. 13A). One advantage of an embodiment having aperture 460A is that
connector 430 is adjustably positionable on at least one of first busbar 420 and second
busbar 422.
[0048] The clamping portion 452 is coupled to the first mounting portion 450 and is configured
and arranged to extend over a portion of the first busbar 420. The clamping portion
452 is configured to operatively impart a clamping force in a third direction indicated
by arrow F, i.e., toward the second busbar 422 when the second busbar 422 is disposed
between the clamping portion 452 and the first busbar 420. In an embodiment, the third
direction F is substantially orthogonal to both the first and second directions. In
an embodiment, the clamping portion 452 further comprises a resilient pivoting member
433 and disposed to operatively impart a clamping force in the third direction F through
clamping portion 452 toward the second busbar 422 during an installation of connector
430. For example, during an installation of connector 430, a mounting force generally
in the third direction F is applied by a user to the second mounting plate portion,
such as through the at least one fastener 432, thereby causing a flexing or bending
of resilient pivoting member 433 whereby clamping portion 452 imparts a clamping force
in the third direction F.
[0049] In an embodiment, the clamping portion 452 comprises a first hinge portion 470, a
first contact portion 472, a second contact portion 474, and a coupling portion 476.
In an embodiment, the first hinge portion 470 extends outwardly from an end of the
first mounting portion 450 at an acute angle relative to the first mounting portion
450. The first contact portion 472 is coupled to and disposed between the first hinge
portion 470 and the second contact portion 474. In an embodiment, the first contact
portion 472 is disposed generally perpendicular to the first mounting portion 450.
The second contact portion 474 is coupled to and disposed between the first contact
portion 472 and the coupling portion 476. The coupling portion 476 extends generally
perpendicular to the second contact portion 474 and is coupled to the second mounting
portion 454. In an embodiment, the second mounting portion 454 extends generally perpendicular
to the portion 476. In an embodiment, clamping portion 452 is configured to contact
the top surface 422A of the second busbar 422. In other embodiments an intermediate
plate, such as a conductive shim (not shown) may be disposed between the clamping
portion 452 and the second busbar 422.
[0050] The second mounting portion 454 is coupled to the clamping portion 452. The second
mounting portion 454 is configured to be coupled to the first busbar 420 such that
the second busbar 422 is fixedly held between the clamping portion 452 and the first
busbar 420, and the second busbar 422 is electrically coupled to the first busbar
420. For example, in one embodiment, the second mounting portion 454 defines at least
one second mounting portion aperture 500 extending therethrough and sized and disposed
to operably align with a corresponding at least one aperture 421 defined in the first
busbar 420.
[0051] In an embodiment, the at least one fastener 432, such as a bolt, is disposed to extend
through the second mounting portion aperture 500 and the corresponding at least one
aperture 421 defined in first busbar 420 and is coupled to a first nut 433.
[0052] Referring to FIGS. 14-18, a flowchart of a method for coupling the electrical connector
430 to the first busbar 420 and the second busbar 422 in accordance with another exemplary
embodiment will now be explained.
[0053] At step 600, the user provides the electrical connector 430 having the first mounting
portion 450 comprising the receiving portion 460 formed therein, the clamping portion
452 coupled to an end of the first mounting portion 450, and the second mounting portion
454 coupled to an end of the clamping portion 452. The second mounting portion 454
having at least one second mounting portion aperture 500 defined therethrough.
[0054] At step 602, the user inserts an end portion 461 of the first busbar 420 into the
receiving portion 460 of the first mounting portion 450 (as shown in FIGS. 14 and
15) such that the clamping portion 452 extends over a portion of the first busbar
420 extending in a first direction.
[0055] At step 604, the user disposes a second busbar 422 to extend in a second direction
substantially perpendicular to the first direction, and between the clamping portion
452 and the first busbar 420 (as shown in FIGS. 14 and 15).
[0056] At step 606, the user applies a force in the third direction F substantially orthogonal
the first and second directions, to move the clamping portion 452 toward the second
busbar 422 (as shown in FIGS. 16 and 17) such that clamping portion 452 imparts a
clamping force in the third direction F, i.e., toward the second busbar 422 to electrically
couple the second busbar 422 and the first busbar 420.
[0057] At step 608, the user fastens the connector 430 to the first busbar 420 by disposing
a portion of the bolt 432 through the at least one second mounting portion aperture
500 and through an corresponding aperture of the first busbar 420 and coupling a threaded
end of the bolt 432 to a first nut.
[0058] Embodiments of the electrical connectors and methods for coupling the connectors
to busbars described herein provide a substantial advantage over prior art electrical
connectors and methods. In particular, the electrical connectors couple together two
busbars without having to drill holes in both busbars.
[0059] While the invention has been described in detail in connection with only a limited
number of embodiments, it should be readily understood that the invention is not limited
to such disclosed embodiments. Additionally, while various embodiments of the invention
have been described, it is to be understood that aspects of the invention may include
only some of the described embodiments. Accordingly, the invention is not to be seen
as limited by the foregoing description, but is only limited by the scope of the appended
claims.
1. An electrical connector (30), comprising:
a first mounting portion (40);
a first clamping portion (41) coupled to the first mounting portion (40), the first
clamping portion (41) having a first coupling tab (42) and a second coupling tab (44);
the first coupling tab (42) extending from the first mounting portion (40) in a first
direction, the first coupling tab (42) having first and second apertures (100, 102)
extending therethrough;
the second coupling tab (44) extending from the first mounting portion (40) in the
first direction, the first and second coupling tabs (42, 44) defining a first gap
(50), the second coupling tab (44) having third and fourth apertures (110,112) extending
therethrough, the third and fourth apertures (110, 112) being aligned with the first
and second apertures (100, 102), respectively;
the first and third apertures (100,110) configured to receive a first fastener;
the second and fourth apertures (102,112) configured to receive a second fastener;
the first gap (50) being sized to clamp a first busbar (20) between the first coupling
tab (42) and the second coupling tab (44), the first busbar (20) being disposed between
the first fastener and the second fastener;
the first and second coupling tabs (42,44) being configured to form an electrical
connection with the first busbar (20) in the first gap (50), characterized in
a second mounting portion (240);
a second clamping portion (241) coupled to the second mounting portion (240), the
second clamping portion having a third coupling tab (242) and a fourth coupling tab
(244);
the third coupling tab (242) extending from the second mounting portion (240) in a
second direction opposite to the first direction, the third coupling tab (242) having
fifth and sixth apertures (300, 302) extending therethrough;
the fourth coupling tab (244) extending from the second mounting portion (240) in
the second direction, the third and fourth coupling tabs (242, 244) defining a second
gap (250), the fourth coupling tab (244) having seventh and eighth apertures (310,
312) extending therethrough, the seventh and eighth apertures (310, 312) being aligned
with the fifth and sixth apertures (300, 302), respectively;
the fifth and seventh apertures (300, 310) configured to receive a third fastener;
the sixth and eighth apertures (300, 312) configured to receive a fourth fastener;
the second gap is sized to receive a second busbar (22);
the third and fourth coupling tabs (242, 244) being configured to form an electrical
connection with the second bus bar in the second gap.
2. The electrical connector (30) of claim 1, wherein the first and second fasteners are
configured to extend between the first coupling tab (42) and the second coupling tab
(44).
3. The electrical connector (30) of claim 1 or claim 2, wherein the first and second
fasteners are first and second bolts (60, 62), respectively.
4. The electrical connector (30) of any preceding claim, wherein the first mounting portion
(40) and the first and second coupling tabs (42, 44) are constructed of an electrically
conductive material.
5. The electrical connector (30) of any preceding claim, wherein the electrically conductive
material is copper.
6. The electrical connector (30) of any preceding claim, wherein the first mounting portion
(40) is block-shaped.
7. The electrical connector (30) of any preceding claim, wherein the first and second
coupling tabs (42, 44) have first and second grooves (121, 123), respectively, disposed
proximate to the first mounting portion (40), wherein the first and second coupling
tabs (42, 44) are bendable proximate the first and second grooves (121, 123), respectively,
toward one another.
8. The electrical connector (30) of any preceding claim, wherein the third and fourth
fasteners are configured to extend between the third coupling tab (242) and the fourth
coupling tab (244).
9. The electrical connector (30) of any preceding claim, wherein the third and fourth
fasteners are third and fourth bolts, respectively.
10. The electrical connector (30) of any preceding claim, wherein the second mounting
portion (454) and the third and fourth coupling tabs (242, 244) are constructed of
an electrically conductive material.
11. The electrical connector (30) of any preceding claim, wherein the second mounting
portion (240) is block-shaped.
12. The electrical connector (30) of any preceding claim, wherein the third and fourth
coupling tabs (242, 244) have first and second grooves (321, 323), respectively, disposed
proximate to the second mounting portion (240), wherein the third and fourth coupling
tabs (242, 244) are bendable proximate the first and second grooves (321, 323), respectively,
toward one another.
1. Elektrischer Verbinder (30), der Folgendes umfasst:
einen ersten Montageabschnitt (40),
einen ersten Klemmabschnitt (41), der mit dem ersten Montageabschnitt (40) gekoppelt
ist, wobei der erste Klemmabschnitt (41) eine erste Kopplungslasche (42) und eine
zweite Kopplungslasche (44) hat,
wobei sich die erste Kopplungslasche (42) von dem ersten Montageabschnitt (40) in
eine erste Richtung erstreckt, wobei die erste Kopplungslasche (42) eine erste und
eine zweite Öffnung (100, 102) hat, die sich dadurch erstrecken,
wobei sich die zweite Kopplungslasche (44) von dem ersten Montageabschnitt (40) in
die erste Richtung erstreckt, wobei die erste und die zweite Kopplungslasche (42,
44) eine erste Spalte (50) definieren, wobei die zweite Kopplungslasche (44) eine
dritte und eine vierte Öffnung (110, 112) hat, die sich dadurch erstrecken, wobei
die dritte und die vierte Öffnung (100, 112) jeweils mit der ersten und zweiten Öffnung
(100, 102) ausgerichtet sind,
wobei die erste und die dritte Öffnung (100, 110) konfiguriert sind, um ein erstes
Befestigungselement aufzunehmen,
wobei die zweite und die vierte Öffnung (102, 112) konfiguriert sind, um ein zweites
Befestigungselement aufzunehmen,
wobei die erste Spalte (50) bemessen ist, um eine erste Sammelschiene (20) zwischen
die erste Kopplungslasche (42) und die zweite Kopplungslasche (44) zu klemmen, wobei
die erste Sammelschiene (20) zwischen dem ersten Befestigungselement und dem zweiten
Befestigungselement angeordnet ist,
wobei die erste und die zweite Kopplungslasche (42, 44) konfiguriert sind, um eine
elektrische Verbindung mit der ersten Sammelschiene (20) in der ersten Spalte (50)
zu bilden, gekennzeichnet durch
einen zweiten Montageabschnitt (240),
einen zweiten Klemmabschnitt (241), der mit dem zweiten Montageabschnitt (240) gekoppelt
ist, wobei der zweite Klemmabschnitt eine dritte Kopplungslasche (242) und eine vierte
Kopplungslasche (244) hat,
wobei sich die dritte Kopplungslasche (242) von dem zweiten Montageabschnitt (240)
in eine zweite Richtung, entgegengesetzt zu der ersten Richtung erstreckt, wobei die
dritte Kopplungslasche (242) eine fünfte und eine sechste Öffnung (300, 302) hat,
die sich dadurch erstrecken,
wobei sich die vierte Kopplungslasche (244) von dem zweiten Montageabschnitt (240)
in die zweite Richtung erstreckt, wobei die dritte und die vierte Kopplungslasche
(242, 244) eine zweite Spalte (250) definieren, wobei die vierte Kopplungslasche (244)
eine siebte und eine achte Öffnung (310, 312) hat, die sich dadurch erstrecken, wobei
die siebte und die achte Öffnung (310, 312) jeweils mit der fünften und sechsten Öffnung
(300, 302) ausgerichtet sind,
wobei die fünfte und die siebte Öffnung (300, 310) konfiguriert sind, um ein drittes
Befestigungselement aufzunehmen,
wobei die sechste und die achte Öffnung (302, 312) konfiguriert sind, um ein viertes
Befestigungselement aufzunehmen,
wobei die zweite Spalte bemessen ist, um eine zweite Sammelschiene (22) aufzunehmen,
wobei die dritte und die vierte Kopplungslasche (242, 244) konfiguriert sind, um eine
elektrische Verbindung mit der zweiten Sammelschiene in der zweiten Spalte zu bilden.
2. Elektrischer Verbinder (30) nach Anspruch 1, wobei das erste und das zweite Befestigungselement
konfiguriert sind, um sich zwischen der ersten Kopplungslasche (42) und der zweiten
Kopplungslasche (44) zu erstrecken.
3. Elektrischer Verbinder (30) nach Anspruch 1 oder 2, wobei das erste und das zweite
Befestigungselement jeweils ein erster und ein zweiter Bolzen (60, 62) sind.
4. Elektrischer Verbinder (30) nach einem der vorhergehenden Ansprüche, wobei der erste
Montageabschnitt (40) und die erste und die zweite Kopplungslasche (42, 44) aus einem
elektrisch leitenden Material hergestellt sind.
5. Elektrischer Verbinder (30) nach einem der vorhergehenden Ansprüche, wobei das elektrisch
leitende Material Kupfer ist.
6. Elektrischer Verbinder (30) nach einem der vorhergehenden Ansprüche, wobei der erste
Montageabschnitt (40) blockförmig ist.
7. Elektrischer Verbinder (30) nach einem der vorhergehenden Ansprüche, wobei die erste
und die zweite Kopplungslasche (42, 44) jeweils eine erste und eine zweite Nut (121,
123) haben, die in der Nähe des ersten Montageabschnitts (40) angeordnet sind, wobei
die erste und die zweite Kopplungslasche (42, 44) jeweils in der Nähe der ersten und
der zweiten Nut (121, 123) zueinander biegbar sind.
8. Elektrischer Verbinder (30) nach einem der vorhergehenden Ansprüche, wobei das dritte
und das vierte Befestigungselement konfiguriert sind, um sich zwischen der dritten
Kopplungslasche (242) und der vierten Kopplungslasche (244) zu erstrecken.
9. Elektrischer Verbinder (30) nach einem der vorhergehenden Ansprüche, wobei das dritte
und das vierte Befestigungselement jeweils ein dritter und ein vierter Bolzen sind.
10. Elektrischer Verbinder (30) nach einem der vorhergehenden Ansprüche, wobei der zweite
Montageabschnitt (454) und die dritte und die vierte Kopplungslasche (242, 244) aus
einem elektrisch leitfähigen Material hergestellt sind.
11. Elektrischer Verbinder (30) nach einem der vorhergehenden Ansprüche, wobei der zweite
Montageabschnitt (240) blockförmig ist.
12. Elektrischer Verbinder (30) nach einem der vorhergehenden Ansprüche, wobei die dritte
und die vierte Kopplungslasche (242, 244) jeweils eine erste und eine zweite Nut (321,
323) haben, die in der Nähe des zweiten Montageabschnitts (240) angeordnet sind, wobei
die dritte und die vierte Kopplungslasche (242, 244) jeweils in der Nähe der ersten
und der zweiten Nut (321, 323) zueinander biegbar sind.
1. Connecteur électrique (30), comprenant :
une première partie de montage (40) ;
une première partie de fixation (41) accouplée à la première partie de montage (40),
la première partie de fixation (41) comportant une première languette d'accouplement
(42) et une deuxième languette d'accouplement (44) ;
la première languette d'accouplement (42) s'étendant à partir de la première partie
de montage (40) dans une première direction, la première languette d'accouplement
(42) étant traversée par des première et deuxième ouvertures (100, 102) ;
la deuxième languette d'accouplement (44) s'étendant à partir de la première partie
de montage (40) dans la première direction, les première et deuxième languettes d'accouplement
(42, 44) définissant un premier espace (50), la deuxième languette d'accouplement
(44) étant traversée par des troisième et quatrième ouvertures (110, 112), les troisième
et quatrième ouvertures (110, 112) étant respectivement alignées avec les première
et deuxième ouvertures (100, 102) ;
les première et troisième ouvertures (100, 110) étant conçues pour recevoir un premier
élément de fixation ;
les deuxième et quatrième ouvertures (102, 112) étant conçues pour recevoir un deuxième
élément de fixation ;
le premier espace (50) étant dimensionné pour fixer une première barre omnibus (20)
entre la première languette d'accouplement (42) et la deuxième languette d'accouplement
(44), la première barre omnibus (20) étant disposée entre le premier élément de fixation
et le deuxième élément de fixation ;
les première et deuxième languettes d'accouplement (42, 44) étant conçues pour former
une connexion électrique avec la première barre omnibus (20) dans le premier espace
(50), ledit connecteur électrique étant caractérisé par :
une seconde partie de montage (240) ;
une seconde partie de fixation (241) accouplée à la seconde partie de montage (240),
la seconde partie de fixation comportant une troisième languette d'accouplement (242)
et une quatrième languette d'accouplement (244) ;
la troisième languette d'accouplement (242) s'étendant à partir de la seconde partie
de montage (240) dans une seconde direction opposée à la première direction, la troisième
languette d'accouplement (242) étant traversée par des cinquième et sixième ouvertures
(300, 302) ;
la quatrième languette d'accouplement (244) s'étendant à partir de la seconde partie
de montage (240) dans la seconde direction, les troisième et quatrième languettes
d'accouplement (242, 244) définissant un second espace (250), la quatrième languette
d'accouplement (244) étant traversée par des septième et huitième ouvertures (310,
312), les septième et huitième ouvertures (310, 312) étant respectivement alignées
avec les cinquième et sixième ouvertures (300, 302) ;
les cinquième et septième ouvertures (300, 310) étant conçues pour recevoir un troisième
élément de fixation ;
les sixième et huitième ouvertures (302, 312) étant conçues pour recevoir un quatrième
élément de fixation ;
le second espace étant dimensionné pour recevoir une seconde barre omnibus (22) ;
les troisième et quatrième languettes d'accouplement (242, 244) étant conçues pour
former une connexion électrique avec la seconde barre omnibus dans le second espace.
2. Connecteur électrique (30) selon la revendication 1, dans lequel les premier et deuxième
éléments de fixation sont conçus pour s'étendre entre la première languette d'accouplement
(42) et la deuxième languette d'accouplement (44).
3. Connecteur électrique (30) selon la revendication 1 ou 2, dans lequel les premier
et deuxième éléments de fixation sont respectivement des premier et deuxième boulons
(60, 62).
4. Connecteur électrique (30) selon l'une quelconque des revendications précédentes,
dans lequel la première partie de montage (40) et les première et deuxième languettes
d'accouplement (42, 44) sont fabriquées dans un matériau électroconducteur.
5. Connecteur électrique (30) selon l'une quelconque des revendications précédentes,
dans lequel le matériau électroconducteur est le cuivre.
6. Connecteur électrique (30) selon l'une quelconque des revendications précédentes,
dans lequel la première partie de montage (40) est en forme de bloc.
7. Connecteur électrique (30) selon l'une quelconque des revendications précédentes,
dans lequel les première et deuxième languettes d'accouplement (42, 44) ont respectivement
des première et seconde rainures (121, 123) disposées à proximité de la première partie
de montage (40), les première et deuxième languettes d'accouplement (42, 44) pouvant
être pliées l'une vers l'autre à proximité respective des première et seconde rainures
(121, 123).
8. Connecteur électrique (30) selon l'une quelconque des revendications précédentes,
dans lequel les troisième et quatrième éléments de fixation sont conçus pour s'étendre
entre la troisième languette d'accouplement (242) et la quatrième languette d'accouplement
(244).
9. Connecteur électrique (30) selon l'une quelconque des revendications précédentes,
dans lequel les troisième et quatrième éléments de fixation sont respectivement des
troisième et quatrième boulons.
10. Connecteur électrique (30) selon l'une quelconque des revendications précédentes,
dans lequel la seconde partie de montage (454) et les troisième et quatrième languettes
d'accouplement (242, 244) sont fabriquées dans un matériau électroconducteur.
11. Connecteur électrique (30) selon l'une quelconque des revendications précédentes,
dans lequel la seconde partie de montage (240) est en forme de bloc.
12. Connecteur électrique (30) selon l'une quelconque des revendications précédentes,
dans lequel les troisième et quatrième languettes d'accouplement (242, 244) ont respectivement
des première et seconde rainures (321, 323) disposées à proximité de la seconde partie
de montage (240), les troisième et quatrième languettes d'accouplement (242, 244)
pouvant être pliées l'une vers l'autre à proximité respective des première et seconde
rainures (321, 323).