Patent Document

BACKGROUND OF THE INVENTION 
     1. Field of the Invention 
     The present invention relates to communication of a data signal over a power distribution system. More particularly, the present invention relates to a use of an inductive coupler for coupling of a data signal via a conductor in a power transmission cable. 
     2. Description of the Related Art 
     In power line communication (PLC), a data coupler couples a data signal between a power line and a communications device, such as, for example, a modem. Radio frequency (rf) modulated data signals can be coupled to and communicated over medium and low voltage power distribution networks. 
     An example of such a data coupler is an inductive coupler. A power line inductive coupler is basically a transformer whose primary is connected to the power line and whose secondary is connected to the communications device, such as the modem. Examples of inductive couplers and their use are described in U.S. Pat. No. 6,452,482, U.S. patent application Ser. No. 10/429,169 and U.S. patent application Ser. No. 10/688,154, all of which are assigned to the assignee of the present application, and the disclosures of which are incorporated herein by reference. 
     The inductive couplers achieve a series coupling, which is capable of launching PLC signals with frequencies from below 4 megahertz (MHz) through in excess of 40 MHz along overhead and underground power cables. Unfortunately, in most cases, the power line wires cannot be interrupted. This limits, to a “single turn winding”, the primary winding passing through the inductive coupler. Where the power line impedance is higher than the modem impedance, impedance matching in the data coupler is difficult because while the primary winding is limited to the single turn, the secondary winding cannot be less than a single turn. 
     Magnetic circuits including inductive couplers exhibit non-linear properties, such as the non-linearity of the circuit&#39;s Magnetic Flux Density vs. Applied Magnetizing Force (B-H) curve. This non-linearity, in conjunction with the magneto-motive force rising from zero to a maximum, twice each cycle of the power frequency, causes distortion. The distortion includes amplitude modulation of the transmitted and received signals. The modem or other communication device will begin to suffer data errors at some threshold level of this distortion. 
     Accordingly, there is a need for an inductive coupler and a corresponding circuit that improves impedance matching between the power line and the communication device or modem. There is a further need for an inductive coupler that reduces distortion of the transmitted and received signals. The apparatus and method of the present invention provides for series coupling of a data signal via a conductor and circuit on a power transmission cable that improves impedance matching and reduces distortion of the signals. 
     SUMMARY OF THE INVENTION 
     It is an object of the present invention to provide an improved coupler for coupling a data signal to a conductor in a power transmission cable. 
     It is another object of the present invention to provide such a coupler that is inexpensive and has a high data rate capacity. 
     It is a further object of the present invention to provide such a coupler that can be installed without interrupting service to power customers. 
     These and other objects of the present invention are achieved by a method for configuring components for power line communications, comprising installing an inductive coupler that employs a power line conductor as a primary winding; connecting a communications device to a secondary winding of the inductive coupler; and connecting an rf signal transformer between the secondary winding and the communications device, in which a turns ratio of the rf signal transformer is 2:1. 
     In a further embodiment, an arrangement of components for coupling data between a power line and a communications device is provided. The arrangement comprises an inductive coupler that employs a power line conductor as a primary winding, and an rf signal transformer for connecting a communications device to a secondary winding of the inductive coupler. The rf signal transformer has a turns ratio of 2:1. 
     In another embodiment, an inductive coupler for coupling a data signal between a communications device and a power line is provided, comprising: a magnetic core having an aperture formed by a first section and a second section; and a secondary circuit having a winding passing through the aperture as a secondary winding connected to the communications device. The aperture permits the power line to pass therethrough as a primary winding and the inductive coupler has a primary inductance of about 1.5 μH to about 2.5 μH. 
     In yet another embodiment, an inductive coupler for coupling a data signal between a communications device and a power line is provided. The inductive coupler comprises: a split magnetic core having an aperture formed by a first section and a second section; and a secondary circuit having a winding passing through the aperture as a secondary winding connected to the communications device. The first and second sections form a gap therebetween and the aperture permits the power line to pass therethrough as a primary winding. 
     In yet a further embodiment, an inductive coupler for coupling a data signal between a communications device and a power line is provided, comprising: a primary winding which employs the power line and a secondary circuit having a secondary winding connected to the communications device. The inductive coupler has a path loss of less than about 10 dB. 
     The aperture of the magnetic core can have a diameter of about 1.5 inches. The magnetic core has a radial thickness that can be less than the diameter of the aperture. The gaps in the magnetic core may be about 30 mils. The magnetic core can weigh less than about 10 pounds. The magnetic core may be made of nano-crystalline magnetic material. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         FIG. 1  is an illustration of an arrangement of a power line and an inductive coupler for data communication, in accordance with the present invention; 
         FIG. 2  is a schematic representation of the data communication arrangement of  FIG. 1  with an impedance matching circuit for the inductive coupler; 
         FIG. 3  is a perspective view of an inductive coupler having a magnetic core, a primary winding and a secondary winding; 
         FIG. 4  is a cross-sectional view of the inductive coupler of  FIG. 3 ; and 
         FIG. 5  is an illustration of a Magnetic Flux Density vs. Applied Magnetizing Force (B-H) curve showing the non-linearity for a typical ferrite material. 
     
    
    
     DETAILED DESCRIPTION OF THE INVENTION 
     Overhead and underground transmission lines may be used for the bi-directional transmission of digital data called Power Line Communications (PLC) or Broadband Over Power Lines (BPL). Such transmission lines cover the path between a power company&#39;s transformer substation and one or more medium voltage-low voltage (MV-LV) distribution transformers placed throughout a neighborhood. The MV-LV distribution transformers step the medium voltage power down to low voltage, which is then fed to homes and businesses. 
     The present invention relates to a use of a coupler in a medium voltage grid. The coupler is for enabling communication of a data signal via a power transmission cable. It has a first winding for coupling the data signal via a conductor of the power transmission cable, and a second winding, inductively coupled to the first winding, for coupling the data signal via a data port. 
     Referring to  FIG. 1 , an illustration of an arrangement of a power line being used for data communication, is shown. A power line or cable  200  has an inductive coupler  220  situated thereon. 
     Power line  200  serves as a first winding  225  of coupler  220 . A second winding  235  of coupler  220  is coupled to a port  255  through which data is transmitted and received. Thus, cable  200  is enlisted for use as a high frequency transmission line, which can be connected to communications equipment such as a modem (not shown), via coupler  220 . 
     Coupler  220  is an rf transformer. The impedance across the primary, i.e., first winding  225 , of such a transformer is negligible at the frequencies used for conducting power. 
     Referring to  FIG. 2 , the cable  200  and coupler  220 , as described above with respect to  FIG. 1 , are again shown, with similar features represented by the same reference numerals. Also shown is a second power conductor  260 , representing a second primary wire of different phase or representing a neutral wire. Where cables  200  and  260  are overhead lines, the characteristic impedance Z o  of overhead lines to differential signals is at least on the order of 100 ohms. The primary winding  225  “sees” this impedance twice, i.e., once on each end of the coupler  220 , for a total impedance of at least on the order of 200 ohms. 
     Modem  375  has an impedance that is typically on the order of about 50 ohms. Impedance matching through use of the proper turns ratio at the coupler  220  cannot be accomplished where the cable  200  is to be left undisturbed. Thus, under these conditions, the turns ratio at the coupler  220  is 1:1 with only a single turn used for the primary and secondary windings. This means that the impedance seen from the secondary winding is nominally the same as the impedance seen by the primary winding, i.e., on the order of 200 ohms. 
     To improve the impedance matching for the PLC with use of the modem  375  having the characteristic impedance described above, an rf signal transformer  300  is connected between the secondary winding  235  of the coupler  220  and the modem. The rf transformer  300  has a primary winding  325  and a secondary winding  335 . Based upon the impedance characteristics described above for the power line  200  and the modem  375 , the turns ratio for the rf signal transformer  300  should be 2:1. 
     Referring to  FIGS. 3 and 4 , an inductive coupler  400  is shown, which is used as described above with respect to coupler  220  of  FIGS. 1 and 2 . Coupler  400  has a magnetic core  500 , comprising core sets  565  and  566 . A plastic packaging material, i.e., plastic layers  570  and  571 , can be used to bind core sets  565  and  566  together. Magnetic core  500  includes an aperture  520 . Phase line  200  passes through an upper section  521  of aperture  520 . A secondary winding  510  and a secondary insulation  575  pass through a lower section  522  of aperture  520 . Magnetic core  500  is thus a composite split core that can be used in an inductive coupler and allows for placement of the inductive coupler  400  over an energized power line, e.g., energized phase line  200 . 
     Aperture  520  is preferably oblong or oval so as to accommodate the phase line  200 , that may be of a large diameter, and the secondary insulation  575  that may be a thick layer of insulation. Such an oblong or oval shape can be achieved, for example, by configuring split core  500  with a first section and a second section, i.e., an upper core  525  and a lower core  530 , that are horseshoe-shaped to provide a racecourse shape for magnetic core  500 , thereby accommodating phase line  200  being large and secondary insulation  575  being thick. 
     Upper and lower cores  525  and  530  are magnetic and have a high permittivity. Upper and lower cores  525  and  530  act as conductors to high voltage since voltage drop is inversely proportional to capacitance and capacitance is proportional to permittivity. Upper core  525  is in contact with phase line  200 . Thus, upper core  525  is energized to avoid intense electric fields near the phase line  200 , which also avoids local discharges through the air. 
     Upper and lower cores  525  and  530  may optionally be placed in electrical contact with each other, so as to preclude a voltage difference between them. Such voltage difference, if sufficiently large, would cause a discharge through the air gap  535  between them, generating electrical noise, which could interfere with coupler operation and could generate interference with radio receivers in the vicinity. Optionally, upper and lower cores  525  and  530  may be coated with a semiconducting layer that would further reduce electric fields in the region of the cores, so precluding discharge. 
     During receipt of a data signal, the impedance of magnetization inductance of the primary winding of the coupler  400  is in shunt with the signal. In order to prevent most of the signal current from flowing through the magnetization inductance of the coupler  400  and failing to reach the modem when receiving a signal, the impedance of the primary winding of the coupler should not be much smaller than the rf characteristic impedance of the power line  200 . Similarly, during transmission of the signal, most of the transmitter current would flow through the magnetization inductance of the coupler  400  and not through power line  200 , if the impedance of the primary winding of the coupler were much smaller than the rf characteristic impedance of the power line. 
     The magnitude of the rf impedance of the primary winding of coupler  400  can be approximated by:
 
 |Z|≈ 2 πfL   p  
 
where f is the frequency in MHz and L p  is the primary inductance in microhenries. This approximation ignores losses across the coupler  400 . For a magnetic coupling coefficient k approaching unity, the primary winding impedance and the impedance of the magnetization inductance are nearly equal.
 
     To minimize the receiving and transmitting effects of the primary inductance L p  of the coupler  400 , the magnitude of the primary winding impedance |Z| should be a significant portion of the characteristic impedance of the power line  200 . However, since the power line  200  is to be left undisturbed and is thus limited to a single turn, the turns ratio of coupler  400  cannot be utilized to achieve this minimization. 
     A desired primary inductance can be achieved through manipulation of the magnetic core  500 . The upper and lower magnetic cores  525  and  530  must provide a magnetic circuit with a sufficiently low magnetic resistance. The magnetic resistance of the upper and lower magnetic cores  525  and  530  is proportional to the magnetic path length l (mean circumference of the cores) and inversely proportional to the cross-sectional area A and to the permeability μ:
 
 L˜ 1 /R   mag  and  R   mag   ˜l /(μ A )
 
Therefore:
 
 L˜μA/l  
 
where the cross-sectional area A is the product of the radial thickness Y (shown in  FIG. 4 ) of the magnetic core  500  and its longitudinal dimension X (shown in  FIG. 3 ). Of course, due to manufacturing constraints, the radial thickness Y and longitudinal dimension X of the magnetic core  500  are not without limit.
 
     The lower bound for the magnetic path length l is determined at least in part by the diameter of the largest wire that the coupler  400  can accommodate, as well as by the thickness of the insulation  575  around the secondary winding  510 . For typical medium voltage conductors, the inner diameter D inner  of magnetic core  500  should be about 1.5 inches. 
     It has been found that the radial thickness Y should be less than the inner diameter D inner . This prevents the magnetic path length l along the outer diameter D outer  from far exceeding the magnetic path length along the inner diameter D inner . Since the magneto-motive force is inversely proportional to the magnetic path length l, the magnetic path along the inner diameter D inner  would saturate at a far lower AC power current than the magnetic path along the outer diameter D outer . The magnetic material along the outer portion of the magnetic core  500  can thus be more efficiently utilized if the longitudinal dimension X, rather than the radial thickness Y, is increased. 
     At radio frequencies up to tens of megahertz, available magnetic materials are limited in both permeability and maximum magnetic flux density. In general, lower permeability materials have a higher maximum flux density. 
     Referring to  FIGS. 3 through 5 , an example of the non-linear properties of coupler  400 , and magnetic circuits in general, is shown in the B-H curve of a typical ferrite material. To mitigate distortion of the transmitted and received signals due to such non-linearity, air gap  535  can be introduced into the magnetic circuit of the coupler  400 . Air gap  535  is a spacer in the magnetic core  500  on one or more pole faces of the magnetic core. 
     It has been discovered that for a coupler frequency response extending downwards as low as 4 MHz, the primary inductance of coupler  400  should reach at least 1.5 microhenries (μH). For a wideband coupler where the upper frequency limit is many times larger than a low frequency cutoff, there is a tradeoff between the benefit of a lower low frequency cutoff due to increased inductance and the increased coupler to line attenuation due to leakage inductance. This leakage inductance is due to the flux leakage at the air gaps  535  and the limited permeability of the magnetic core material. 
     Leakage inductance appears in series between the power line  200  and the secondary winding  510  of the coupler  400 , and its reactance increases with frequency. For a coupler intended to preferably operate in the range from below 4 MHz through in excess of 40 MHz, and using a practical range of magnetic coupling coefficients, it has been discovered that the primary inductance of the coupler  400  should not exceed 2.5 μH. Based upon this, it has been discovered that the optimal primary inductance for the coupler  400  is in the range of 1.5 μH to 2.5 μH. 
     It has also been discovered that for a coupler  400  having an inner diameter D inner  of at least 1.5 inches and a magnetic core weight not exceeding about ten pounds, the equivalent relative permeability μ, including core and air gap, is in the range of about 200 to 300. In order to reach a power current capacity of at least 200 Amps rms, it was discovered that air gaps  535  having a thickness or spacing of about 30 mils or about 0.76 mm should be used on each of two pole faces of the magnetic core  500 , providing about triple the magnetic resistance of the magnetic cores  500 . The air gaps  535  increase the current capacity by a factor of about eight, while reducing the inductance by a factor of about three. The air gaps  535  reduce the effects of variations in incidental gaps caused by geometrical imperfections at the mating of the pole faces of the magnetic core  500  and reduce the effects of manufacturing variations in core material permeability. Additionally, the air gaps  535  reduce rf core losses. It has been discovered that the magnetic cores  500  should have an initial relative permeability μ in the range of 600 to 1000. 
     These unexpected results occurred for the use of a ferrite magnetic material for the magnetic core  500 . Ferrite cores typically saturate at flux densities in the 2800 to 4800 Gauss range. Powdered metal cores have a higher saturation flux densities than ferrite cores, but a relative permeability μ no higher than 100. The total weight of the powdered metal cores needed would be several times that needed by ferrite cores. It has been discovered that coupler  400 , as described above, when used with an impedance matching transformer, such as, for example, transformer  300  of  FIG. 2 , can achieve path losses in the 6 to 10 dB range per coupler when used on overhead lines. 
     For power lines conducting currents in excess of about 200 Amps, ferrite core material may be replaced by nano-crystalline cores. With the dimensions discussed here, power currents of 600 Amps may be accommodated without excessive saturation. 
     While the instant disclosure has been described with reference to one or more exemplary embodiments, it will be understood by those skilled in the art that various changes may be made and equivalents may be substituted for elements thereof without departing from the scope thereof. In addition, many modifications may be made to adapt a particular situation or material to the teachings of the disclosure without departing from the scope thereof. Therefore, it is intended that the disclosure not be limited to the particular embodiment(s) disclosed as the best mode contemplated for carrying out this invention, but that the invention will include all embodiments falling within the scope of the appended claims.

Technology Category: 5