[0001] The invention which is the subject of this application relates to a connector for
use in the connection of electrical conductors such as for example the connection
of respective ends of conductors, branch connections of conductors.
[0002] Use of mechanical connectors to join electrical conductors and allow the passing
of electricity between said conductors through the connector is well known. The conventional
manner of connecting said conductors is to provide a channel in which said conductor
ends can be placed, the provision of covers to place onto the channels to enclose
the conductors in the channels, a sleeve to go over the covers and clamping screws
to secure the conductors in the connector and hence form the electrical connection.
While this form of connector is used on a relatively large scale, there are several
disadvantages with the same.
[0003] A first disadvantage is that the use of the clamping screws means that the length
of the connector has to be such so as to accommodate the number of clamping screws
which are required to be used and this can mean that the connector is in fact of a
length determined mainly or solely by the number of clamping screws. The additional
length of the connector means that the same can become bulky and, when one considers
that the connector is typically required to be fitted in a confined space underground,
and often in inclement conditions as, for example, the space may be flooded in wet
weather, it will be appreciated that a bulky connector is not a desirable feature.
[0004] Another problem with the use of clamping screws is that although the mechanical connector
tends to have an overall circular cross section, the channel and hence conductor,
is not located along the central longitudinal axis of the same due to the need for
a larger thickness of body portion to be provided where the clamping screw threads
are to be formed. This means that when the connector is placed for in line connection
of the conductor ends, the conductor ends are offset to one side of the longitudinal
axis of the connector. This, in turn, can cause the fitter difficulty in insulating
the same and/or applying insulating shrouds around the connector.
[0005] A further problem is that there are now a number of different forms of conductors
being used in the industry which are of different cross sectional shape and, in many
instances, the conventional mechanical conductors are not satisfactory in connecting
certain conductor types such as, for example, a conductor with a substantially circular
cross section.
[0006] The aim of the present invention is to provide a mechanical connector for use in
the connection of electrical conductors to provide electrical connection between the
same and to provide the connector in a form which can be of relatively short length,
is easy to fit in confined areas and can be adapted to allow the connection of conductors
of different shapes and/or sizes. Furthermore, it is an aim of the present invention
to provide a mechanical connector for electrical conductors which can be provided
in a manner to match any of the known forms of mechanical connectors in terms of arrangement
of the respective conductors which are to be joined together and therefore provide
a range of mechanical connectors which can be used in accordance with conventional
requirements.
[0007] In accordance with a first aspect of the invention there is provided a connector
for the connection of the ends of at least two electrical conductors in an end to
end manner to allow electrical connection between the said conductors, said connector
including at least one body portion, said body portion having at least one port at
one end thereof for the reception of a conductor end therein, a collet arrangement
for location around said conductor and location within said port with the conductor,
and a clamping means, engageable with the body portion such that movement of the clamping
means to exert a clamping force with respect to the body portion causes the clamping
means to move inwardly of the port and exert a moving action on the collet and characterised
in that the movement of the collet causes the same to move to a fixing position in
the body portion port with respect to the conductor and/or connector body and causes
the collet to exert a gripping action on the conductor and thereby secure the conductor
in position within the connector.
[0008] Typically, the connector is used to connect a number of conductor ends together although
the connection means used for respective conductors may vary and may be in a number
of different arrangements. It should therefore be appreciated that the connection
arrangement for each conductor may or may not be formed in accordance with the invention.
For example, in one embodiment, the connector includes port openings at each end which
extend into the length of the connector body, with a conductor end being introduced
into each port opening and secured therein with respective collet and clamping means
arrangements in accordance with the invention.
[0009] In one embodiment, the body portion includes one port passing along the length thereof
with two openings, each receiving a conductor end and clamping arrangement. Alternatively,
the connector body portion includes two ports, one extending inwardly from each of
the body portion ends but not being linked.
[0010] In a yet further embodiment, the connector is formed by two connector body portions.
Typically, each body portion is arranged with a port protruding inwardly from one
end of each and, at the other end, an engagement formation is provided which, by connection
of the mutual engagement formations allow the two body portions to be brought into
contact and secured in contact to form the connector.
[0011] In a yet further embodiment, the connector has at a first end, a port or number of
ports and at a second end, a port or number of ports to allow the connection of more
than two conductor ends.
[0012] In one embodiment, the collet is formed from one or more components, and, in use,
the components are placed on the conductor and positioned in the port with the conductor.
Typically, weakened lines and/or slots are provided at spaced locations on the collet
to allow compression of the same during movement and the clamping of the collet on
the conductor and connector within the connector body.
[0013] Typically, the walls of the port which receives the collet taper inwardly so as to
form a substantially frustoconical shape as they depend inwardly of the connector
from the port opening.
[0014] Typically, when the clamping means is first moved inwardly of the port, the collet
is caused to move further inwardly of the port along the conductor but, at the same
time, the typically frustoconical shaping of the walls of the port, cause the collet
to move inwardly and onto the conductor as the collet moves along to exert greater
contact with the conductor. After a period of movement, the collet comes to a position
where it can no longer move further along or inwardly of the port and becomes fixed
in position with respect to the conductor and port and exerts a gripping action on
the conductor. At this point, in one embodiment, where no further lateral movement
of the conductor or collet is possible, further movement of the clamping means inwardly
of the port causes at least part of the collet to collapse inasmuch that the same
moves inwardly towards the conductor and exerts a gripping action on the conductor.
[0015] The clamping means can be of any suitable form which allows the progressive movement
of the same inwardly of the port of the connector body when it is required to clamp
the conductor in position within the connector. In one embodiment, the clamping means
is threaded and engages with a thread formed at the opening of the port such that
rotation of the clamping means with respect to the connector body causes the same
to progressively move inwardly of the port until the collet reaches a fixed position.
[0016] In use, it is important to ensure that the conductor is secured in the connector
with the required tensile strength. In one embodiment a visual indication is provided
on the connector to allow the fitter of the connector to be sure that the required
tensile strength has been reached in securing the conductor in position. In an alternative
and preferred embodiment, the clamping means are provided with a shearing feature
such that when a predetermined selected clamping torque has been reached to cause
the required tensile strength to be achieved, a portion of the clamping means shears
thereby providing the visual indication required and, yet further, ensuring that the
clamping means is not overly inserted into the container body. Furthermore the line
of shear and shape of same can be such so as to leave the connector "clean lined"
and available for the application of a shroud thereover and/or insulation via a heatshrink
material or moulded shroud without risk of the shroud being damaged by the line of
shear.
[0017] In one embodiment the clamping means is provided with a shear line which shears when
a predetermined clamping torque is exerted by the clamping means. Typically the clamping
means comprises a main portion which is threaded for location with the connector body
portion, a shear line and a detachable drive portion, which when the clamping means
shears is detached from the clamping means. Preferably at the same time as, or after,
the drive portion shears from the main portion of the clamping means, further detachment
of the drive portion occurs to cause the same to split and hence be removable from
the conductor. In one embodiment the shear line is formed so as to cause the splitting
of the drive portion to occur or alternatively a separate shear line is included or,
yet further, engagement means can be released to allow the drive portion to be detachable
from the position round the conductor and hence leave only the main portion of the
clamping means which is in contact with the connector body remaining.
[0018] Typically, when fitting the connector of the invention, the conductor ends are at
least partially encapsulated in insulating material and, prior to the fitting of the
connector, a portion of the insulating material at the conductor end is removed to
allow the connector to be fitted thereon and bring about the electrical connection.
[0019] The collet, as previously stated, can be formed of one piece or formed from a number
of components brought together around the conductor. The internal faces of the collet
may be smooth or may be provided with protrusions thereon to improve the grip into
the conductor. Yet further, the inner walls of the collet can be shaped to allow the
receipt in a close fitting arrangement of the conductor. Thus, for example, if the
conductor is of a circular cross section, then the inner walls of the collet will
be curved in a similar manner so that a substantially circular passage is defined
therein, or, if the conductor has a 90° or 120° sector shape, as is also possible
in commercial use, the inner walls of the collet can be formed accordingly to receive
the conductor in close fitting relationship. Alternatively, the inner walls of the
collet and/or the body may be so formed as to be range taking inasmuch that they contact
with a sufficient surface of the conductor to exert the gripping action thereon, regardless
of the particular cross sectional shape of the conductor. Thus, it will be appreciated
that the connector in accordance with the invention can be range taking and/or adaptable
so as to take into account the dimensions and shapes of the conductors to be joined
together.
[0020] Thus in the use of the connector in accordance with the invention, for each conductor
end which is to be connected in the manner described, a clamping means and collet
are inserted over and around the end of the conductor, said conductor and collet moved
into a port in the connector and the clamping means engaged with and moved inwardly
of the port, to move the collet further inwardly of the frustoconically shaped port
causing the collet to move onto the conductor as the collet moves along the port to
exert greater contact with the conductor, and after a period of movement, the collet
comes to a position where it can no longer move longitudinally of the port and further
movement of the clamping means inwardly of the port causes at least part of the collet
to collapse to exert a gripping action on the conductor.
[0021] Specific embodiments of the invention will now be described with reference to the
accompanying drawings, wherein:-
Figure 1 illustrates the components of a connector in accordance with one embodiment
of the invention.
Figure 2 illustrates in schematic fashion, cross sectional views of part of the connector
and drive means along lines AA and CC respectively of Figure 1 required to form a
connector for conductors in accordance with the invention;
Figures 3a and 3b illustrate a cross sectional view along line B-B of a collet in
accordance with the invention, before and after use respectively in securing a conductor
end;
Figure 4 illustrates the components of Figure 2 in position to secure a conductor
end in the connector;
Figures 5a and 5b illustrate alternative embodiments of the collet arrangement in
end elevation;
Figure 6 illustrates an elevation of the collet;
Figures 7a to 7e illustrate various embodiments of connector configurations in section,
each configuration within the scope of the invention;
Figures 8 - 10 illustrate drawings of an embodiment of the connector body, collet
and clamping means respectively;
Figures 11 and 12 illustrate the components of the Figures 8-10 in open and closed
positions respectively, and
Figure 13 illustrates one form of clamping means drive portion.
[0022] Referring firstly to Figures 1 and 2, there are illustrated the components of one
embodiment of the connector and in Figure 2 one end of the said connector.
[0023] There are illustrated conductor ends 2, 2' which are to be joined by the connector
4. The connector 4 is shown in section in Figure 2 and comprises a body with a port
6 defined at at least one end. The port is provided for the receipt of the conductor
end 2 as indicated by arrow 8 and also receipt of a collet 10 which is placed onto
the conductor as indicated by the arrow 12. With the collet and conductor end located
in the port 6, the clamping means 16 which will already have been placed around the
bared conductor end 2 can be rotated as indicated by arrow 18 so as to engage with
a threaded section 20 in the port 6. As the clamping means is rotated, so it moves
inwardly of the port as indicated by arrow 22 to a position as shown in Figure 4.
Continued rotation of the clamping means 16 causes the collet to move along the frustoconically
shaped walls of the port 6 and as it does so, the walls of the collet are forced inwardly
towards each other so as to close the gap 25 as shown in Figure 3a and reach a point
whereby the same can no longer move along the longitudinal axis of the port 6. At
this point, continued rotation of the clamping means causes the portions 24A and 24B
as shown in Figure 3a to partially collapse along the weakening sections 26 and by
doing so, the same move onto the conductor and exert a gripping force on the same.
[0024] Figure 3A illustrates the formation of the collet before the tightening occurs and
the position of the collet after the gripping effect is shown in Figure 3B.
[0025] The clamping means 16 is also preferably provided with a shear line 27, which, upon
a predetermined and selected clamping torque being reached when the clamping means
is turned, shears as illustrated in Figure 4. At this stage the connector collet is
in the position and condition as shown in Figures 3b and Figure 4 to exert the required
tensile and other clamping forces on the conductor so as to secure the same in the
port. When the clamping means shears along the shear line 27 the drive portion 29
has sheared off and the fitter can be assured that the appropriate clamping torque
has been reached. Typically the shear line 27 is defined by a weakened line with narrower
cross section on the clamping means. The cross section size and shaping of the shear
line 27 is predetermined with respect to the required clamping toque, the size of
conductor, shape of the conductor, material used for the clamping means and indeed
any relevant detail can be taken into account such that the drive portion 29 of the
clamping means will shear off when the selected clamping torque on the collet and
conductor is reached. This portion is therefore detachable from the connector leaving
the main portion 31 in engagement with the connector and maintaining the clamping
torque on the connector.
[0026] It should be appreciated that the process described with regard to Figures 1 to 4
can be repeated at the opposing end of the connector or, yet further, an alternative
form of conductor fitting means may be provided for the other conductor end to be
connected via the connector.
[0027] Figures 5a and 5b illustrate two forms of collet arrangement and Figure 5 illustrates
that regardless of the internal shape of the collet, the external shape will be typically
the same so as to allow the same to be acted upon by the inwardly sloping walls of
the port 6 in the connector which forces the walls of the collet together and onto
the conductor. It should however be noted that the formations 24 need not always be
of the same shape and equally, the cone shaped walls 30 of the collet portions equally
need not be the same length at all times and, preferably, will be shortened as much
as possible so as to allow the subsequent length of the connector to be shortened.
[0028] Figure 5a illustrates the collet in use to exert a clamping effect on a conductor
2 with a circular cross section. Figure 5b illustrates a collet with internal formations
to accommodate a conductor 32 in the form of a sector cross section, in this case
a 90° sector, conductor. Thus it will be appreciated that the internal area defined
by the collet for the reception of the conductor can be formed to suit a particular
conductor cross sectional shape. Although not shown, it is possible and in many cases
may be preferable, for the internal surfaces of the collet which are to contact with
the conductor, to be provided with ridges, teeth or other means which can move into
the conductor material to improve the securing of the collet on the conductor during
the clamping operation.
[0029] Figures 7a to 7e illustrate alternative embodiments of the connector in accordance
with the invention. Figure 7a illustrates a connector body 34 in section with first
and second ports 36, 38 which join onto each other and each is for the respective
location of a conductor end therein in accordance with the invention. Figure 7b illustrates
a connector body 40 with ports 42 and 44 which are not linked as shown. Figure 7c
illustrates a connector body which is formed of two connector parts 46, 48, each connector
part having a port 50, 52 respectively for the engagement of a conductor end in accordance
with the invention and furthermore, each connector part is provided with an engagement
formation 54, 56 which, when brought together as shown, allow the two connector parts
to be joined together to form the connector body. Typically, a clamping means such
as a clamping screw, not shown, is passed through the two formations 54, 56 to join
the connector parts 46, 48 together. Figure 7e illustrates a branch connector body
57 with each of the ports 58, 60, 62 used to receive a conductor end. Figure 7d illustrates
a terminal conductor body 63 in which the port 64 receives a conductor end which is
secured therein in accordance with the invention, and a lug 66 is provided with means
68 to allow the same to be attached to apparatus to which the conductor end is used
to supply electricity.
[0030] Figures 8-10 illustrate specific embodiments of a conductor body 100, collet 102
and clamping means 104 respectively.
[0031] Figure 11 illustrates the components of Figures 8 -10 in a fixing position for conductor
ends (not shown) to be located in ports 106,106' respectively. Figure 12 illustrates
how the clamping means 104 can be moved inwardly of the connector body 100 as indicated
by arrows 105 to a closed or clamping position. At this stage, continued turning of
the clamping means results in the drive portions 129 of the clamping means shearing
along shear line 127 and additionally at the same time or thereafter along shear line
133 which is shown in Figure 13. The shear line 133 is provided to ensure that in
addition to the drive portion shearing from the main portion 131 of the clamping means
at the required clamping torque, the drive portion 129 splits in a manner to ensure
that the split parts can be removed from the conductor completely and are not encircling
the same. In one embodiment the shear lines 127 and 133 can be joined so as to form
an integral shear line.
[0032] It should be noted that the form and path of the shear lines 27, 127 and 133 can
take any suitable design form, the important requirement being that upon a selected
clamping torque being reached, the drive portion shears from the main portion of the
clamping means and shears in such as manner so that the drive portion is removable
from the conductor.
[0033] Although not shown, it should be appreciated that the collet can be formed from more
than one component, said components placed around the conductor to form the action
required and herein described.
[0034] Thus it will be appreciated that the connector in accordance with the invention can
be used for any conventional connection requirement but is provided in a form which
represents significant advantages over the prior art.
1. A connector for the connection of the ends of at least two electrical conductors in
an end to end manner to allow electrical connection between the said conductors, said
connector including at least one body portion, said body portion having at least one
port at one end thereof for the reception of a conductor end therein, a collet arrangement
for location around said conductor and location within said port with the conductor
and a clamping means engageable with the body portion such that movement of the clamping
means to exert a clamping force with respect to the body portion causes the clamping
means to move inwardly of the port and exert a moving action on the collet and characterised in that the movement of the collet causes the same to move to a fixing position in the body
portion with respect to the conductor and/or connector body and causes the collet
to exert a gripping action on the conductor and thereby secure the conductor in position
within the connector.
2. A connector according to claim 1 characterised in that the connector is used to connect a number of conductor ends together, with port openings
at each end which extend into the length of the connector body, with a conductor end
introduced into each port opening and secured therein with respective collet and clamping
means arrangements.
3. A connector according to claim 1 characterised in that the body portion includes one port passing along the length thereof.
4. A connector according to claim 1 characterised in that the connector body portion includes two ports, one extending inwardly from each of
the connector body ends.
5. A connector according to claim 1 characterised in that the connector is formed by two connector body portions which are arranged with a
port protruding inwardly from one end of each and, at the other end, mutual engagement
formations are provided which allow the two portions to be brought into contact and
secured to form the connector.
6. A connector according to claim 1 characterised in that the connector comprises, at a first end, a port or number of ports and, at a second
end, a port or number of ports to allow the connection of more than two conductor
ends.
7. A connector according to claim 1 characterised in that the connector is provided with a port and clamping arrangement at one end and, at
the other end, means for securing the connector to a terminal or other item of apparatus.
8. A connector according to claim 1 characterised in that the collet is formed from a number of components, and, in use, the components are
placed on the conductor and positioned in the port with the conductor.
9. A connector according to claim 1 characterised in that the collet includes weakened lines and/or slots to allow compression of the same
during the clamping of the same in position within the connector body.
10. A connector according to claim 1 characterised in that the collet is shaped so as to accommodate conductors of differing cross sectional
shape and/or sizes within a known range of shapes and/or sizes.
11. A connector according to claim 1 characterised in that the clamping means is provided with a shear line which shears when a predetermine
clamping torque is exerted by the clamping means.
12. A connector according to claim 11 characterised in that the clamping means comprises a main portion located with the body portion, a shear
line and a drive portion, which when the clamping means shears is detached from the
clamping means.
13. A connector according to claim 12 characterised in that upon shear the drive portion splits to be removable from the conductor.
14. A connector according to claim 12 characterised in that engagement means on the drive portion are releasable to allow the drive portion to
be removed from the conductor.
15. A method of clamping a conductor end in a connector according to claim 1 characterised in that a clamping means and collet are inserted over and around the end of a conductor,
said conductor and collet moved into a port in the connector and the clamping means
engaged with and moved inwardly of the port, to move the collet further inwardly of
the frustoconically shaped port causing the collet to move onto the conductor as the
collet moves along to exert greater contact with the conductor, and after a period
of movement, the collet comes to a position where it can no longer move longitudinally
of the port and further movement of the clamping means inwardly of the port causes
at least part of the collet to collapse to exert a gripping action on the conductor.
16. A method according to claim 15 characterised in that the clamping means is threaded and engages with a thread formed at the opening end
of the port such that rotation of the clamping member with respect to the connector
body causes the same to progressively move inwardly of the port until the collet reaches
a fixed position.
17. A method according to claim 16 characterised in that the clamping means is provided with a shear line which is formed to shear upon a
predetermined torque level being reached.
18. A method according to claim 17 characterised in that a portion of the clamping means shears off along the shear line when the predetermined
torque level is reached.