NZ739932B2 - An electrical connection system for use in high power applications - Google Patents
An electrical connection system for use in high power applications Download PDFInfo
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- NZ739932B2 NZ739932B2 NZ739932A NZ73993215A NZ739932B2 NZ 739932 B2 NZ739932 B2 NZ 739932B2 NZ 739932 A NZ739932 A NZ 739932A NZ 73993215 A NZ73993215 A NZ 73993215A NZ 739932 B2 NZ739932 B2 NZ 739932B2
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- New Zealand
- Prior art keywords
- electrical connection
- component
- connection system
- coupling
- driving force
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- 230000008878 coupling Effects 0.000 claims abstract description 53
- 238000010168 coupling process Methods 0.000 claims abstract description 53
- 238000005859 coupling reaction Methods 0.000 claims abstract description 53
- 230000005540 biological transmission Effects 0.000 claims abstract description 29
- 230000000712 assembly Effects 0.000 claims description 4
- 238000000429 assembly Methods 0.000 claims description 4
- 230000000694 effects Effects 0.000 claims description 2
- 239000004020 conductor Substances 0.000 description 7
- 239000011810 insulating material Substances 0.000 description 4
- 239000000463 material Substances 0.000 description 3
- 238000005065 mining Methods 0.000 description 2
- 239000003208 petroleum Substances 0.000 description 2
- 238000004880 explosion Methods 0.000 description 1
- 239000002360 explosive Substances 0.000 description 1
- 230000004048 modification Effects 0.000 description 1
- 238000012986 modification Methods 0.000 description 1
- 230000000717 retained effect Effects 0.000 description 1
Abstract
electrical connection system is described. The electrical connection system comprises a first electrical connection component that is suitable for transmission of power with a voltage level greater than 1 kV. The electrical connection system also comprises a second electrical connection component that is suitable for transmission of power with a voltage level greater than 1 kV and arranged for coupling to the first electrical connection component. The electrical connection system comprises a mechanical coupling assembly for imparting a driving force to drive the first and second electrical connection components relative to each other along a central axis of the electrical connection system and between disengaged and engaged conditions. The mechanical coupling assembly is structured to impart a portion of the driving force at a first eccentric position and comprising a transmission that is arranged to transmit a further portion of the driving force to a second eccentric position. The second eccentric position has an angular orientation around the central axis that is different to that of the first eccentric position. that is suitable for transmission of power with a voltage level greater than 1 kV and arranged for coupling to the first electrical connection component. The electrical connection system comprises a mechanical coupling assembly for imparting a driving force to drive the first and second electrical connection components relative to each other along a central axis of the electrical connection system and between disengaged and engaged conditions. The mechanical coupling assembly is structured to impart a portion of the driving force at a first eccentric position and comprising a transmission that is arranged to transmit a further portion of the driving force to a second eccentric position. The second eccentric position has an angular orientation around the central axis that is different to that of the first eccentric position.
Description
AN ELECTRICAL CONNECTION SYSTEM FOR USE IN HIGH POWER
APPLICATIONS
FIELD OF THE INVENTION
The present invention relates to an electrical connection system for use in
high power applications. In particular, though not exclusively, the present invention
relates to an electrical connection system suitable for use in high power applications in
demanding environments such as the petroleum or mining industry.
BACKGROUND OF THE INVENTION
Reliable electrical connections are crucial in high power applications, such as
powering of heavy electrical machinery often used in the mining or petroleum industry.
In these applications the electrical cables transmit high currents at voltages of one or
more kV.
Typical electrical connectors used in the art have a plurality of pins or sockets, each
being connected to a respective core of an electrical cable. Depending on the specific
application, the connectors must comply with specific requirements or standards. The
compliance of the connectors with the relevant standards is examined by a certifying
body.
In an explosive environment, for example, particular precaution must be taken and a
flame path may be required between connectors to reduce likelihood of explosions.
The flame path typically is formed between a plug and a receptacle by positioning a
cylindrical surface that surrounds contacts and/or electrical leads of the plug inside a
respective surface of a receptacle. The mechanical tolerance between the cylindrical
surfaces is fine (typically 0.2 to 0.4 mm). As a consequence of the fine mechanical
tolerance, canting or seizing may occur which makes it difficult to engage or disengage
the plug and the receptacle form each other.
SUMMARY OF THE INVENTION
In a first aspect of the present invention there is provided an electrical
connection system that comprises:
a first electrical connection component that is suitable for transmission of power
with a voltage level greater than 1 kV;
17685219_1 (GHMatters) P100881.NZ
a second electrical connection component that is suitable for transmission of
power with a voltage level greater than 1 kV and arranged for coupling to the first
electrical connection component;
wherein the electrical connection system comprises a mechanical coupling
assembly for imparting a driving force to drive the first and second electrical connection
components relative to each other along a central axis of the electrical connection
system and between disengaged and engaged conditions, the mechanical coupling
assembly being structured to impart a portion of the driving force at a first eccentric
position and comprising a transmission that is arranged to transmit a further portion of
the driving force to a second eccentric position, the first and second eccentric positions
having respective angular orientations around the central axis.
The mechanical coupling assembly may be arranged to distribute the driving force in
substantially equal portions exclusively to spaced apart eccentric positions having
respective angular orientations around the central axis. In one embodiment the
mechanical coupling assembly is arranged to distribute the driving force to two spaced
apart positions, such as two eccentric positions that are opposite each other.
The mechanical coupling assembly may comprise a geared component that may
include the transmission and may further comprise a coupling component. The second
electrical connection component may comprise the geared component and the first
electrical connection component may comprise the coupling component. The coupling
component may comprise racks that are positioned to engage with the geared
component. The geared component may comprise a ratcheting system. The racks may
be distributed at the positions around the central axis and at which drive is in use
imparted.
The transmission may have gears that in use transmit a portion of the driving force. In
one specific embodiment the transmission comprises gears that are positioned on one
side portion of the second electrical connection component and are arranged to
distribute portions of the driving force between the first and second eccentric position
around the central axis.
In one embodiment the transmission is arranged such that turning of a first gear, for
example using the ratcheting mechanism, effects turning of a second remote gear at
17685219_1 (GHMatters) P100881.NZ
substantially the same time whereby the portions of the driving force are imparted at
the respective first and second positions around axis at substantially the same time
and rate.
One of the first and second electrical connection components may comprise pins for
engagement with sockets that the other one of the first and second electrical
connection components may comprise.
The second electrical connection component is in one specific embodiment a
receptacle and the first electrical connection component is a plug arranged for
engagement with the receptacle. The geared component with the transmission may
form a part of the receptacle. The electrical connection system may further comprise
racks that form a part of the plug. The racks may be positioned for engagement with
gears of the geared arrangement, which may be arranged to move a connection face
of the plug incrementally into the receptacle until the plug is mechanically and
electrically coupled with the receptacle.
The first electrical connection component may have a first end for coupling to the
second electrical connection component and may be arranged for coupling to a
machine cable at a second end.
In one embodiment the second electrical connection component has a first end for
coupling to the first electrical connection component and may be arranged for coupling
to a machine cable at a second end.
In an alternative embodiment the second electrical connection component has two
ends and is arranged for coupling to two first electrical connection components, one at
each end. In this embodiment the second electrical connection component may be a
receptacle and the
first electrical connection components may be plugs. The second electrical connection
component may in this embodiment comprise two of the above-described mechanical
coupling assemblies each comprising the transmission and arranged for imparting
portions of driving forces at at least two eccentric position around the central axis to
drive the first electrical connection components relative to the second electrical
connection component along the central axis between disengaged and engaged
17685219_1 (GHMatters) P100881.NZ
conditions.
The invention will be more fully understood from the following description of specific
embodiments of the invention. The description is provided with reference to the
accompanying drawings.
BRIEF DESCRIPTION OF THE DRAWINGS
Figures 1 and 2 are views of an electrical connection system in accordance
with an embodiment of the present invention;
Figure 3 is a views of an electrical connection system in accordance with an
embodiment of the present invention; and
Figure 4 is view of a component of an electrical connection component in
accordance with an embodiment of the present invention.
DETAILED DESCRIPTION OF SPECIFIC EMBODIMENTS
Embodiments described herein provide an electrical connection system for
connecting to machine cables suitable for high power applications. The electrical
connection system comprises first and second electrical connection components that
are arranged for coupling to each other. For example, the first electrical connection
component may be a plug comprising pins and the second electrical connection
component may be a receptacle comprising sockets. The electrical connection
components are suitable for transmission of power with voltage levels greater than 1
kV (such as 3.3 kV or 11 kV).
The electrical connection system comprises a mechanical coupling assembly for
imparting a driving force to drive the first and second electrical connection components
relative to each other along a central axis of the electrical connection system between
disengaged and engaged conditions. The mechanical coupling assembly is structured
to apply a first portion of the driving force at a first eccentric position and comprises a
transmission for transmission of a second portion of the driving force to a second
eccentric position. The first and second eccentric positions have different angular
orientations around the axis.
The mechanical connection assembly further comprises in this embodiment a
17685219_1 (GHMatters) P100881.NZ
component (such as a ratcheting system) for applying the driving force manually to the
mechanical connection assembly and the transmission then distributes portions of the
driving force in substantially equal portions between the first and second eccentric
positions around the central axis. The first and second positions are in this
embodiment opposite to each other.
The first and second electrical connection components have cylindrical flame path
surfaces between which a flame path is defined when the first and second electrical
connection components are engaged. The mechanical tolerance between the
cylindrical flame path surfaces is 0.2 to 0.4 mm, which is small compared to the
relatively large scale of the electrical connection components. As the driving force is
distributed to two spaced apart positions around the central axis (in this case opposite
positions), the likelihood of mechanical seizing or canting can be reduced when the
electrical connection components are moved between the engaged and disengaged
conditions along the central axis.
Referring initially to Figures 1 and 2, the electrical connection system in accordance
with an embodiment of the present invention is now described. Figures 1 and 2 show a
first electrical connection component that is provided in the form of a plug 100 and is
connected to a machine cable 107. Further, Figures 1 show a second electrical
connection component that is provided in the form of a receptacle 101. In this
embodiment the receptacle 101 is arranged for coupling to two of the plugs 100 (only
one plug 100 is shown), one at each end.
The receptacle 101 and the plug 100 are suitable for transmission of power with a
voltage level greater than 1 kV (in this embodiment 3.3 kV). The receptacle 101 and
the plug 100 have respective housings 109, 111 that define internal regions. In the
embodiment described, the housings 111 and 109 have substantially cylindrical
shapes and are formed form a high density polymeric material.
The receptacle 101 has a contact assembly 106 that comprises sockets for electrically
connection with pins of a corresponding contact assembly of the plugs 100. In the
embodiment described the contact assembly 106 comprises three separate electrical
conductors each being arranged in a respective phase tube. The phase tubes
comprise an insulating material that surrounds a respective electrical conductor, and a
17685219_1 (GHMatters) P100881.NZ
conductive material that surrounds the insulating material and is arranged to be
electrically connectable (indirectly) to an earth terminal of a machine cable 107
connected to the plug 100.
The housing 109 of the plug 100 has a machine cable end and a connection end and
incorporates the above-mentioned contact assembly (not shown) that has pins and
thimbles for connection to respective cores of the machine cable 107. In the
embodiment described the contact assembly of the plug 100 comprises three separate
electrical conductors each being arranged in a respective phase tube. The phase tubes
comprise an insulating material that surrounds a respective electrical conductor, and a
conductive material that surrounds the insulating material and is arranged to be
electrically connectable to an earth terminal of the machine cable 107.
The receptacle 101 comprises a mechanical connection assembly 108 that has gears
and the plug 100 comprises racks 112. For connecting the plug 100 and the receptacle
101 to each other, the plug 100 is urged into the receptacle 101 by use of the
mechanical connection assembly 108 that engages with the racks 112. This way the
electrical connection assemblies of the plugs 100 couple with the above-described
electrical connection assembly 106 within the receptacle 101.
The mechanical connection assembly 108 forms in this embodiment a part of the
receptacle 101. However, a person skilled in the art will appreciate that alternatively
that mechanical connection assembly 108 may form a part of the plug 100 (in which
case the receptacle 101 would comprise the racks 112).
In this example, the mechanical connection assembly 108 comprises gear wheels 110,
110’, 116 and 116’ (shown in Figure 4) and the gear wheels 116, 116’ form a
transmission that transmits drive between the gear wheels 110 and 110’. The gear
wheels 110, 110’ are arranged to engage in a rack and pinion arrangement with
respective racks 112 that are arranged on upper and lower portions of the plug 100
such that, when the gear wheels 110, 110’ are turned, the plug 100 is urged into, and
retained within, a first end 102 of the receptacle 101.
In this example, the upper gear wheel 110 is turned by a ratchet handle 114. The
ratchet handle 114 is coupled to the upper gear wheel 110 in a ratchet configuration
17685219_1 (GHMatters) P100881.NZ
such that, when the ratchet handle 114 is moved in a first direction, the upper gear
wheel 110 turns, and when the ratchet handle is moved in a second opposite direction
the upper gear wheel 110 does not turn.
The gear wheels 110, 110’, 116, 116’ are housed in a gear housing 118. The gear
housing 118 is sealed so as to prevent the ingress of undesirable materials such as dirt
and moisture, which may otherwise interfere with the operation of the gear wheels 110,
110’, 116, 116’.
Advantageously, and as a result of the gears 116 and 116’ the upper and lower gear
wheels 110, 110’ move in conjunction with one another and substantially
simultaneously. As such, the upper and lower racks 112 are moved into the receptacle
101 at substantially the same time and rate. This facilitates uniform movement of the
plug 100 into the receptacle 101 and reduces the likelihood of mechanical canting.
The mechanical connection system 108 also comprises a latch 120. The latch 120 can
be closed after the plug 100 has been received within the receptacle 101 and is
arranged to fit over respective flanges of the first end 102 of the receptacle 101 and the
plug 100 so as to retain the plug 100 within the receptacle 101. The latch 120 can be
locked in position, for example by using a padlock or similar (not shown).
Although the mechanical connection system 108 has been described above in relation
to coupling the plug 100 to the first end 102 of the receptacle 101, it will be appreciated
that the second end 104 of the receptacle 101 comprises in this embodiment a
correspondingly configured electrical contact assembly and a mechanical connection
assembly 108 for mechanically coupling with the second plug (not shown).
In a variation of the above-described embodiment the receptacle 101 may only be
arranged for coupling to a plug 100 at the first end 102 and may be arranged for
coupling to a machine cable at the second end. In this variation the receptacle 101 is
coupled to the machine cable at the second end in the same manner as the plug 100.
Referring now to Figures 4, an electrical connection system in accordance with an
alternative embodiment of the present invention is now described. Figure 3 shows a
receptacle 301 and a plug 300 in an engaged condition. The plug 300 and the
17685219_1 (GHMatters) P100881.NZ
receptacle 301 are related to the plug 100 and the receptacle 101, respectively, as
described above, but have different shapes. The receptacle 301 comprises a
mechanical coupling assembly 308 that corresponds to the above-described
mechanical coupling assembly 108. The mechanical coupling assembly 308 is
operable by leavers 314 of a ratcheting system and distributes a driving force between
two opposite eccentric positions around the central axis of the electrical connection
system. The receptacle 301 has a housing formed from a high density polymeric
material and comprises an electrical coupling assembly for coupling with an electrical
coupling assembly of the plug 300.
Figure 4 shows a front view of components of the plug 300. Shown are racks 312 for
engagement with respective gears of the mechanical coupling assembly 208. Further,
recesses 314 for receiving electrical conductors and phase tubes are visible.
For further details of electrical contact components reference is being made to the
applicant’s co-pending PCT international application numbers ;
, and .
It will be appreciated by persons skilled in the art that numerous variations and/or
modifications may be made to the invention as shown in the specific embodiments
without departing from the spirit or scope of the invention as broadly described. For
example, the electrical connection system may be arranged to impart drive at more
than two positions around the central axis of the electrical connection system. Further,
the positions at which drive is imparted may not necessarily be opposite positions. For
example, drive may be imparted at three eccentric positions that are equally spaced
around the central axis using a suitable transmission.
The reference that is being made to the applicant’s co-pending PCT international
applications does not constitute an admission that the disclosure of the applicant’s co-
pending PCT international applications is part of the common general knowledge in
Australia or any other country.
17685219_1 (GHMatters) P100881.NZ
THE
Claims (15)
1. An electrical connection system that comprises: a first electrical connection component that is suitable for transmission of power 5 with a voltage level greater than 1 kV; a second electrical connection component that is suitable for transmission of power with a voltage level greater than 1 kV and arranged for coupling to the first electrical connection component; wherein the electrical connection system comprises a mechanical coupling 10 assembly for imparting a driving force to drive the first and second electrical connection components relative to each other along a central axis of the electrical connection system and between disengaged and engaged conditions, the mechanical coupling assembly being structured to impart a portion of the driving force at a first eccentric position and comprising a transmission that is arranged to transmit a further portion of 15 the driving force to a second eccentric position, the first and second eccentric positions having respective angular orientations around the central axis, and wherein the transmission has gears that in use transmit a portion of the driving force and is arranged such that turning of a first gear effects turning of a second remote gear at substantially the same time whereby the portions of the driving force 20 are imparted at the respective first and second eccentric positions around the central axis at substantially the same time and rate.
2. The electrical connection system of claim 1 wherein the mechanical coupling assembly is arranged to distribute the driving force exclusively to two spaced apart 25 eccentric positions having respective angular orientations around the central axis.
3. The electrical connection system of claim 1 or 2 wherein the mechanical coupling assembly is arranged to distribute the driving force to two eccentric positions that are substantially opposite each other.
4. The electrical connection system of any one of the preceding claims wherein the mechanical coupling assembly comprises a geared component that includes the transmission and further comprises a coupling component. 35
5. The electrical connection system of claim 4 wherein the second electrical 17685219_1 (GHMatters) P100881.NZ connection component comprises the geared component and the first electrical connection component comprises the coupling component, and wherein the coupling component comprises racks that are positioned to engage with the geared component at positions around the central axis and at which in use drive is in use imparted.
6. The electrical connection system of claim 4 or 5 wherein the geared component comprises a ratcheting system.
7. The electrical connection system of any one of the preceding claims wherein the 10 transmission comprises gears that are positioned on one side portion of the second electrical connection component and are arranged to distribute portions of the driving force between the first eccentric position and the second eccentric position.
8. The electrical connection system of any one of the preceding claims wherein the 15 second electrical connection component is a receptacle and the first electrical connection component is a plug arranged for engagement with the receptacle.
9. The electrical connection system of claim 8 wherein the mechanical connection assembly comprises a geared component with the transmission and forms 20 a part of the receptacle.
10. The electrical connection system of claim 8 or 9 further comprising racks that form a part of the plug and wherein the racks are positioned for engagement with gears of a geared arrangement.
11. The electrical connection system of any one of the preceding claims wherein the first electrical connection component has a first end for coupling to the second electrical connection component and is arranged for coupling to a machine cable at a second end.
12. The electrical connection system of any one of the preceding claims wherein the second electrical connection component has a first end for coupling to the first electrical connection component and is arranged for coupling to a machine cable at a second end. 17685219_1 (GHMatters) P100881.NZ
13. The electrical connection system of any one of claims 1 to 11 wherein the second electrical connection component has two ends and is arranged for coupling to two first electrical connection components, one at each end. 5
14. The electrical connection system of claim 13 wherein the first electrical connection component is one of two first electrical connection components that are plugs and wherein the second electrical connection component is a receptacle.
15. The electrical connection system of claim 14 wherein the mechanical coupling 10 assembly is one of two mechanical coupling assemblies and wherein the second electrical connection component comprises the two mechanical coupling assemblies each comprising a respective transmission and arranged for imparting portions of driving forces at at least two eccentric position around the central axis to drive the first electrical connection components relative to the second electrical connection 15 component along the central axis between disengaged and engaged conditions. 17685219_1 (GHMatters) P100881.NZ
Applications Claiming Priority (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| PCT/AU2015/000563 WO2017041128A1 (en) | 2015-09-10 | 2015-09-10 | An electrical connection system for use in high power applications |
Publications (2)
| Publication Number | Publication Date |
|---|---|
| NZ739932A NZ739932A (en) | 2021-05-28 |
| NZ739932B2 true NZ739932B2 (en) | 2021-08-31 |
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