The present application relates to an electrical connector and to a method of connection. In particular it relates to an electrical connector for connecting high frequency telecommunications signals on to an electricity transmission or distribution network.
Such connectors may be required for use with mains electricity distribution and/or transmission networks (generally referred to herein as power networks). In particular, such connectors are useful in order to safely connect high frequency signals from a telecommunications network on to a power network for powerline telecommunications applications. Such powerline telecommunications systems are described in the applicant's co-pending published International patent applications, numbers PCT/GB95/02023, PCT/GB95/00894, PCT/GB95/00893, PCT/GB95/02163 and PCT/GB97/02937. The teaching and disclosures of these five patent applications should be referred to in relation to the present invention and are incorporated herein by reference.
As it is now becoming more desirable to connect telecommunications networks to power networks so that telecommunication signals can be transmitted along those power networks, it becomes important to find suitable methods for making such connections and suitable apparatus for doing so. The power network SUBSTITUTE SHEET (RULE 26) environment is a particularly hostile environment for telecommunications signals and for work generally, due to the high voltages and currents typically involved.
The equipment which may be used on such power networks is therefore usually highly regulated and strictly controlled; these considerations should be taken into account when determining how to connect to the power network.
Particular problems arise when attempting to connect telecommunications signals to a power network at or near a distribution transformer point on the power network. At a distribution transformer point, typically, a number of polyphase electrical distribution feeder cables are interconnected via fuse links and bus-bar sections to a transformer secondary and/or primary winding. However, given that such distribution transformer points are usually (a) above ground and (b) therefore accessible, these can typically be some of the more convenient points at which to access the power network for telecommunications purposes.
The present invention aims to provide a method of connecting a telecommunications network on to a power network at or near such a bus-bar section, and also aims to provide apparatus suitable for making a connection.
Accordingly, in a first aspect, the present invention SUBSTITUTE SHEET (RULE 26) provides a method of coupling a telecommunications signal to a plurality of power cables, each cable being connected in a line to a bus-bar, the method including the steps of selecting one of the cables located substantially in the centre of the line and either coupling the telecommunications signal to the selected cable or coupling the signal to the bus-bar in the vicinity of the selected cable. By "in the vicinity"
is preferably meant at or near the selected cable e.g.
nearer to the selected cable than to any of the other cables connected to the bus-bar.
Where a telecommunications signal is to be connected to a plurality of power cables, one aim is usually to ensure a roughly equal distribution of telecommunications signal power among the power cables.
By making the physical connection in the vicinity of one of the central cables in the line, as proposed above, this helps to ensure that the signal power is approximately distributed in as equal away as possible.
Preferably, the telecoms signals have a carrier frequency of at least 1 MHZ.
While a single phase application is possible, typically the power cables in question will be polyphase power cables (e.g. containing 2, 3, 4 or more phases) and there will therefore be a plurality of bus-bars with one bus-bar for each phase, plus probably a neutral bus-bar. Clearly the respective phases of each cable SUBSTTTUTE SHEET {RULE 26) 4 PG"TJGB98/03499 will each be connected to a respective bus-bar of the appropriate phase. As an example, if each cable is a three phase cable (e. g. red, yellow and blue phases), then there will be three live bus-bars (red, yellow and blue phases) and each yellow phase of each cable will be connected to the yellow phase bus-bar, each blue phase of each cable to the blue phase bus-bar etc. In such a case, the telecommunications signal will preferably be coupled to each of the bus-bars in the vicinity of the connections of the respective phases of the selected cable. The telecommunications signal may be coupled to as many or as few of the available phases/conductors as desired in eg balanced-balanced, balanced-unbalanced or unbalanced-unbalanced or unbalanced-balanced modes.
If there are an odd number of cables arranged in, for example, a line then the selected cable will preferably be the centre cable in the line. However, if there are an even number of cables in the line then the selected cable may be one of the two centre cables in the line or possibly the coupling may be made at a point e.g.
substantially centrally between the two centre cables in the line. If the arrangement is other than in a line then the decision of where to make the physical coupling will be based on which location is likely to provide the most even telecommunications signal power distribution to the power cables - which is of course the same consideration as applies when the power cables are in a line.
SUBSTITUTE SHEET (RULE 26) As mentioned above, each electricity distribution feeder cable (and indeed each phase of each cable) may be connected to the respective bus-bars by separate fuse links. Such fuse links, or fuse holders, are 5 generally relatively easily removable from a system in order that the fuses can be replaced when necessary.
However the fuse links are usually of an approved design and so substantial modifications to that design might necessitate further approval.
Accordingly, in a second aspect, the present invention provide a fuse holder for use in a power network, the holder including means for holding a fuse element, means for connecting the fuse element to the power network, and means for coupling a telecommunications signal to the power network.
By incorporating means for coupling a telecommunications signal to the power network in to the fuse holder, a simple coupling mechanism is provided which is relatively easy to retro-fit to existing power networks.
Preferably, the fuse holder is of a standard approved type, for example containing a fuse link held in place by one or more clamps and also incorporating one or more fixing means for fixing the fuse holder in place on a bus-bar once the fuse holder has been inserted into or onto the bus-bar. Preferably the means for coupling the telecommunications signal to the power SUBSTITUTE SHEET (RULE 26) network includes at least one capacitive coupler (e. g.
a capacitor) and a connector means by which a telecommunications signal cable can be connected to the means for coupling. The means for coupling may also include an in-line fuse.
This second aspect of the present invention may be used in connection with the first aspect of the present invention or alternatively may be used in systems where the first aspect of the present invention is not used and/or appropriate.
Embodiments of the present invention will now be described by way of example with reference to the accompanying drawings in which:
Figure 1 is a schematic view of a typical distribution cable and bus-bar connection arrangement, showing how a telecommunications signal may be coupled to the arrangement according to the present invention.
Figure 2 is a side view of an embodiment of a fuse holder according to the present invention.
Figure 3 is a top view of the embodiment of figure 2 along the line of arrow 3.
Figure 4 is a cross sectional view along the line 4-4 of figure 2.
SUBSTITUTE SHEET (RULE 26) Figure 5 is a side view of the embodiment of figure 2 in the direction of arrow 5.
Figure 6 is a schematic view of the coupling means included in the embodiment of figure 2.
Figure 7 is a schematic diagram of a polyphase to earth RF signal interface configuration according to an embodiment of the present invention.
Figure 8 is a schematic diagram of a phase to phase RF
signal interface configuration according to an embodiment of the present invention.
Figure 1 shows a system of connections between a plurality (in this case 7) distribution cables 15 and a bus-bar system. In this case the bus-bar system consists of four bus-bars lI-14; these are three live phase bus-bars 11-13 (red, blue and yellow phases respectively) and a neutral bus-bar 14. For simplicity, no connections to the neutral bus-bar have been shown although in practice each distribution cable would usually have a further connection to the neutral bus-bar.
Each distribution cable is a polyphase cable, in this case including three phases each of which is on a separate conductor 16, 17, 18. The respective phase conductors of each distribution cable are each connected to the appropriate bus-bars i.e. the red SUBSTITUTE SHEET (RULE 26) _, w.v m .~.~I mwrLW n1 LL~1V Ii v. ~,L~J , '. '~ ' CA 02311551 2000-OS-23 Chas= cond~~ctor to of th= first distriauticr. cGb7.e is cC:~nacted tc the red phase bus-bar .1 a~d so on. =he sewn discributior, cables 15 are arranged in a straight lir.= and thmi= respeL:.ive connections to Lhe bus-bars 11-~,3 are sim_lar=y i.n stra_ght :sires . Each distr i.buci on cable phs.se cor3uctcr _s corrected :.o an appropriate bus-bsr via a fuse holder 19.
r,. ~ccard~.ng to the present invention, i.r. is desixed to ~fl make a eor~ection batwesn a tel?communicsCio:~s signal carr~,ring canCUctor 20 and each of th a swan distributio:~ cables. Tnis =s done by selecrir_g the c~r~t=s.l discrib~stior~ cable 21 in trs line az distribution cab-es ~.nd n~a~:irg the co nection between rha te7.ecommunications signal azd the bua-ba=s aitYar to cable 21 ox' to the b~;s-bars in the ~riC~.nity o~ the correction between cable 21 and tha bus-baxs. In the example shewr., th ° connection betvraan the teletocnmurioa~ions aigna_ .s mach to eacr phase Z4 Conductor of di6tributiori C3.ble 27. zit. the fuse holder 19 wi~ich corrects thos= phase conduc tcrs co their respective bus-baxs. =n. .his Way the signal powex of the ta7.ecnrrimur~icaCions =igrcal 20 is disc~ibuted rsaso~ably eve:ly betw~an the se~ren distr:.butior. cables ~5 'S.
~igura 2 o-hows a aLIS° holder (genexa.It indi sated ,~'~'l GCcor~inC to a:~ wspeet of the presant iwT~r.t' ar.. The Fuse zo:~der ?X consists of a ma~.n bcdy moulding 23 30 whica carries a fuse link 24 held in plats by a pair of AMENDED SHEE'~
.. . ~ ..~. ~....,... ..._.,. ~~v. -Lr ' CA 02311551 2000-OS-23 S
bolt c7.~mps 25 aid carrier assc~l.ES 50 tbetter seen in rigors 5)- ~~=en Lhs ~use carrier is lots=e3 in place ir~ or or. a bus-bar socket (usually after having beer. ~usred home a . g . by rr.and) , the iu.se ::o'._der is hall in dace by i : sul ated :bomb screws 26, ~.~hich arc us~~ally rotated cloc'rcwisa to secure =he 'use holder .n dace .
~"~e toss holder shown in figure 2 is~'.mod~.f;ed from a f ...
St&ricat:."d fus° holder 5y the inclusion of a teleconmuricat:.oas signal connector, shaWn generally as Zi. This wll be describe3 in more dttail with ~efer2nce co figure 6.
':.5 Figures 3-5 show other views cf chn fuse holder ?2, as ex~=wined a't~ove.
FiS~.:re 6 shows in ;note detail the t=lecomm:m~ic2tiors swgnal eornector 27 which is inserted into tha slot ;r_ S~
2~ the fuse holder .~3', shown by a dashed line ~.n figure 2.
The conr_ector 27 co:~sists of a.n in=~~'-ared body 60 , ir_sids which arC CoiWa.~.ned various corn;ctor components. ~leczriral connection is made =tom the connector com~onen:s to tht ~use link 2~ cr holder 25 25 via a read 62 which extends out of the insulac_d bcdy 0. ~ detachable RF connection is :nave to the device via a sa=et'y probe 64 which connects to a socket G
The p,~ signal-s are then capaci'ively :oupled 'Via one or more capacitors (63, 65) and an optional fuse o'7 to ti:e 30 cor:nector 62. The value vF the couplir_g capac.=ox(s) AR~L~NDED SHEEP
WO 99I2~614 PCT/GB98/03499 is chosen and their safe working voltages) is dependent upon the RF signal frequency(ies) and the bus-bar phase to phase and/or phase to neutral and/or earth potentials at 50/60Hz (i.e. the relatively high 5 amplitude power components) respectively.
The RF signal should be fed, via the modified fuse links, onto the necessary phase conductors, if appropriate with respect to neutral and/or earth, of 10 the network with the necessary safety earth(s), matching devices (i.e. balanced to unbalanced, unbalanced to balanced, polyphase to neutral earth etc) and over voltage and/or surge protection devices.
Figure 7 illustrates a polyphase to earth RF signal interface configuration. The RF communication signals are interfaced via the unbalanced coaxial port 701 via the resistive splitter/combiner network consisting of resistors 702-705 each of which feed a portion of the RF signals via the coupling capacitors 706-708 onto each of the 3 bus-bars 710, 720 and 730 via fuse links 732-734 respectively. Also the RF signals propagate via the main fuse links 735-737 onto the polyphase cable 740 which is assumed to be of a clad type with a neutral earth sheath. Cable 742, which is another distribution cable, is also assumed to be of a similar type.
The RF chokes (inductors)712-714 provide a low impedance path at 50/60 Hz (i.e. at power frequencies) SUBSTITUTE SHEET (RULE 26) should capacitors 705-708 become short circuit thus enabling fuse links 732-734 to fail to safety. However the chokes 712-714 are constructed such that they have a relatively high impedance with respect to the RF
communication signals and therefore do not attenuate these signals.
The power transformer secondary windings 750-752 are shown for clarity and the neutral or star point 753 is earthed in this configuration. Each of the three major component assemblies 760-762 may be separately housed if required for safety reasons. Components 706-708 and 732-734 are incorporated in their respective main fuse link housings, 735-737 as detailed in figure 2.
Figure 8 illustrates a phase to phase RF signal interface configuration. The RF communication signals are interfaced via the unbalanced coaxial port 801, the balun transformer (consisting of windings 803-805 which might typically be wound on a ferrite ring core), capacitors 806, 807 and fuse links 808, 809 onto bus-bars 810, 811.
Balun transformer windings 803 and 805 provide low impedance paths to earth at 50/60 Hz should capacitors 806 and/or 807 fail to short circuit and thereby enable fuse links 808 and/or 809 to fail to safety. The balun transformer windings 803-805 maintain a relatively high impedance with respect to the RF communication signals and therefore do not attenuate these signals.
SUBSTITUTE SHEET (RULE 26) The RF communication signals applied to bus-bars 810 and 811 are similarly linked to cable 820 via the main fuse links 822 and 823 and similarly onto cable 821 via main fuse links 824 and 825. The power transformer secondary windings 830-832 are shown for clarity and the neutral or star point 833 is earthed in this configuration. Each of the three major component assemblies 840, 841, 842 may be separately housed if required for safety reasons. Components 806, 807 and 808, 809 are incorporated in their respective main fuse link housings 822 and 823 as detailed in figure 2.
The above embodiments of the present invention have been described by way of example only and various alternative features or modifications from what has been described can be made within the scope of the invention, as will be readily apparent to persons skilled in the art.
SUBSTITUTE SHEET (RULE 26)