Distributed impedance injection module for mitigation of the Ferranti effect

Abstract

Disclosed is a method for reducing the variation in voltage, due to Ferranti effect, using the impedance injection capability of distributed impedance injection modules. The Ferranti effect is an increase in voltage occurring at the receiving end of a long transmission line in comparison to the voltage at the sending end. This effect is more pronounced on longer lies and underground lines when the high-voltage power lines are energized with a very low load, when there is a change from a high load to a very light load, or the load is disconnected from the high-voltage power lines of the power grid. This effect creates a problem for voltage control at the distribution end of the power grid.

Claims

1. A method of reducing or eliminating a Ferranti effect in a high voltage transmission line comprising: coupling impedance/voltage injection modules to the high voltage transmission line at spaced apart locations along the high voltage transmission line, the impedance/voltage injection modules each being powered from the high voltage transmission line and having a high voltage transmission line current sensing capability, an impedance/voltage injection capability and a communication capability; and using at least a subset of the impedance/voltage injection modules, sensing current in the high voltage transmission line; and when the high voltage transmission line current indicates that a high voltage transmission line load at a receiving end of the high voltage transmission line is low or zero, injecting an impedance/voltage onto the high voltage transmission line at spaced apart locations along the high voltage transmission line to collectively reduce or cancel a voltage generated by a current charging a line capacitance passing through a line impedance.

2. The method of claim 1 wherein all impedance/voltage injection modules are used to inject the impedance/voltage onto the high voltage transmission line to reduce or cancel the voltage generated by the current charging the line capacitance passing through the line impedance when the high voltage transmission line current indicates that the high voltage transmission line load at a receiving end of the transmission line is low or zero.

3. The method of claim 1 wherein the at least a subset of the impedance/voltage injection modules sense the current in the high voltage transmission line and automatically inject the impedance/voltage onto the high voltage transmission line at spaced apart locations along the high voltage transmission line to collectively reduce or cancel the voltage generated by the current charging the line capacitance passing through the line impedance when the current in the high voltage transmission line indicates that the high voltage transmission line load at the receiving end of the high voltage transmission line is low or zero.

4. The method of claim 3 further comprising receiving information relative to the voltage on the high voltage transmission line at the receiving end of the high voltage transmission line and adjusting the injection of an impedance/voltage onto the high voltage transmission line at spaced apart locations along the high voltage transmission line to further control the voltage at the receiving end of the high voltage transmission line.

5. A method of reducing or eliminating a Ferranti effect in a high voltage transmission line comprising: identifying a low current in the high voltage transmission line using a current sense device within at least a distributed impedance/voltage injection module coupled to the high voltage transmission line; determining an increase in line voltage, due to the Ferranti effect, at a load or substation end due to the low current in the high voltage transmission line; injecting a voltage using at least a selected number of distributed impedance/voltage injection modules to compensate for the increase in line voltage at the load or substation end; thereby correcting the Ferranti effect on the high voltage transmission line.

6. The method of claim 5, wherein the distributed impedance/voltage injection modules are powered from a power drawn from the high voltage transmission line.

7. The method of claim 5, wherein the distributed impedance/voltage injection modules are suspended from the high voltage transmission line and are at a line potential of the transmission line.

8. The method of claim 5, wherein the determined increase in line voltage at the load end of the line due to the Ferranti effect is corrected by a cumulative incremental distributed voltage injection by the distributed impedance/voltage injection modules coupled to the high voltage transmission line.

9. A system for controlling a voltage increase in a high voltage transmission line due to a Ferranti effect, the system comprising: a plurality of distributed impedance/voltage injection modules coupled to the high voltage transmission line; a line current sensing circuit associated with each impedance/voltage injection module; an impedance/voltage injection circuit associated with each impedance/voltage injection module; a voltage sensing and comparison capability at a load/substation end of the high voltage transmission line; and a communication channel from the load/substation end of the high voltage transmission line to the distributed impedance/voltage injection modules for transferring information regarding a voltage sensed at the load/substation end of the high voltage transmission line; wherein when a low current is sensed by the plurality of distributed impedance injection modules and an intimation of over voltage is received over the communication channel, each of the plurality of impedance/voltage injection modules generate and inject an incremental voltage on to the high voltage transmission line in a manner that a cumulative injected voltage from the plurality of impedance/voltage injection modules is sufficient to reduce or overcome the increase in voltage due to the Ferranti effect at the load/substation end of the high voltage transmission line.

10. The system of claim 9, wherein a voltage correction is by equal distributed incremental voltage by each of the plurality of impedance/voltage injection modules.

11. The method of claim 1, wherein the communication capability is any one of a wireless communication capability, a wire line communication capability or a power line communication capability.

12. A method of reducing or eliminating a Ferranti effect in a high voltage transmission line comprising: coupling a plurality of impedance/voltage injection modules to the high voltage transmission line, the impedance/voltage injection modules each being powered from the high voltage transmission line and having an impedance/voltage injection capability and a communication capability; and using at least a current sensing capability available on the high voltage transmission line, sensing a current in the high voltage transmission line; and when the high voltage transmission line current indicates that a high voltage transmission line load at a receiving end of the high voltage transmission line is low or zero, injecting an impedance/voltage onto the high voltage transmission line using the impedance/voltage injection modules to collectively reduce or cancel a voltage generated by a current charging a line capacitance passing through a line impedance.

13. A system for controlling a voltage increase in a high voltage transmission line due to a Ferranti effect, the system comprising: a plurality of distributed impedance/voltage injection modules coupled to the high voltage transmission line; a line current sensing capability coupled to the high voltage transmission line and communicably linked to the impedance/voltage injection modules; a voltage sensing and comparison capability at a load/substation end of the high voltage transmission line; and a communication channel from the load/substation end of the high voltage transmission line to the distributed impedance/voltage injection modules for transferring information regarding a voltage sensed at the load/substation end of the high voltage transmission line; wherein when a low current is sensed by the line current sensing capability and an intimation of over voltage is received over the communication channel, each of a subset of the plurality of impedance/voltage injection modules generate and inject an incremental voltage on to the high voltage transmission line in a manner that a cumulative injected voltage from the plurality of impedance/voltage injection modules is sufficient to reduce or overcome the increase in voltage due to the Ferranti effect at the load/substation end of the high voltage transmission line.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) The drawings are made to point out and distinguish the invention from the prior art. The objects, features, and advantages of the invention are detailed in the description taken together with the drawings.

(2) FIG. 1 is a block diagram of the transmission line as per the prior art.

(3) FIG. 2 is a schematic representation of the (distributed it-model) equivalent circuit of the transmission line of FIG. 1 showing the distributed nature of the resistance, inductance, and capacitance associated with the transmission line.

(4) FIG. 3 is a schematic representation of the lumped constant (-model) equivalent circuit of the transmission line of FIGS. 1 and 2.

(5) FIG. 4A is a phase diagram of the current-voltage relationships illustrating the Ferranti effect and its cause.

(6) FIG. 4B is a phase diagram 410 of the current-voltage relationship after correction voltage has been applied to mitigate Ferranti effect.

(7) FIG. 5 is a block diagram of a first embodiment of a distributed Voltage/Impedance injection module with a multi-turn primary winding.

(8) FIG. 6 is a block diagram of a second embodiment of a distributed voltage/impedance injection module having a plurality of single turn primary windings.

(9) FIG. 7 is a block diagram of the transmission line with distributed voltage/impedance injection modules attached directly to the HV-transmission-lines.

(10) FIG. 8 shows a block diagram representation of a long HV transmission line showing the distributed voltage/impedance injection modules covering each segment of the HV transmission line.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

(11) The invention disclosed herein is generally directed at providing a system and method for controlling or limiting the increase in voltage at the load end of a long transmission line by using impedance/voltage injection modules, such as, but not limited to, those disclosed in U.S. Pat. No. 7,105,952.

(12) A plurality of implementations of injection modules has been proposed by the present inventors to allow balancing of the power transferred over a transmission line by changing the line impedance locally. By making these injection modules intelligent, self-aware, and with local intercommunication capability, it is possible to monitor locally and control the power flow over the high-voltage transmission (HV transmission) lines of the power grid. The distributed injection modules are enabled to recognize changes in the power flow characteristics and inject impedances to compensate for the unwanted changes in the high-voltage (HV) transmission lines.

(13) While these injection modules could be directly connected in series with the transmission line with ground connection, this is not normally done because of the need to provide insulation that can sustain high line voltage differences to ground at each module, which will become prohibitively expensive and also make the modules heavy. In practice, the impedance modules are can be electrically and mechanically connected to the transmission line, and are at line potential, or alternatively only magnetically coupled to the transmission line, but in either case, they are enabled to respond to transmission line current variations. These impedance injection modules are ideal candidates for distributed implementation, as existing high voltage power transmission systems can be retrofitted without disturbing the transmission line itself, though alternate implementation of impedance/voltage injection module installations using movable and other support structures are also usable for correcting the Ferranti effect. (The distributed impedance/voltage injection is described in detail as it is the preferred mode for this application). Thus in substantially all cases, the impedance/voltage injection modules respond to transmission line current and not transmission line voltage. Any transmission line corrections that require line voltage information such as corrections in voltage and power factor by each injection module are made by instructions received by wireless, wireline or power line communication to the module based on current measurements made by that module, other communicably linked modules or other line current measurement capability coupled to the high voltage power lines and again communicably linked to the impedance/voltage injection modules, and voltage measurements made at the next line voltage measurement facility, typically at the next substation.

(14) As previously described, phase diagram FIG. 4A illustrates the Ferranti effect. As can be seen from that FIG. 4A, the Ferranti effect arises from the AC-charging current in the line inductance L (FIG. 3). Accordingly, injection of a correcting impedance/voltage onto the line can reduce or eliminate this component, leaving the {right arrow over (V.sub.R)} 403 component, which can be considered a load characteristic and handled as part of a power factor correction.

(15) FIG. 4B shows the voltage-current vector relationship 410 with the correction voltage vector {right arrow over (V.sub.Cor)} 402 applied to correct the increase in voltage due to Ferranti effect. The resultant voltage vector at the receiver {right arrow over (V.sub.R)}.sub., new 407 is the compensated voltage across the capacitor C.sub.R 303 when the Load.sub.RL 312 is not present or is very low.

(16) FIG. 5 shows an injection module 500 previously disclosed (U.S. patent application Ser. No. 15/055,422) having a transformer 501 with a multi-turn primary winding which is attached to the transmission line by cutting the line and splicing the module in series with the transmission line. The injection module 500 has a controller 504 that senses the changes in current transmitted over the transmission line 102 and voltage information transmitted to the module, and uses them to control the output of a converter 503. Alternatively, the injection module may wirelessly communicate current measurements to the next substation, and the substation, or a separate control station (not shown) wirelessly send specific instructions to the injection module 500 and similar injection modules on the transmission line. The converter 503 generates an impedance (or voltage) that when impressed in a distributed fashion on the transmission line via the transformer 501, can compensate for the changes on the transmission line 102. In this configuration, the module 500 can be electrically connected directly to the power transmission line 102, if desired, and insulated from ground, or allowed to float with respect to the transmission line. The power for the controller is also extracted from the transmission line by a second transformer 502 connected to a power supply module. Any transmission line voltages needed for transmission line control are measured at one or more substations and wirelessly transmitted to the injection modules, or the current measured by the injection modules transmitted to a control location also having the transmission line voltage measurements and the control location transmitting instructions to the injection modules for the desired injection module response.

(17) FIG. 6 shows a second embodiment of intelligent and self-aware injection module 600 previously disclosed (U.S. patent application Ser. No. 15/069,785) that uses a plurality of single turn primary transformers 601 to couple the output produced by the converters 603 to couple the control voltage to the power line 102. A sensor and power supply module 602 that couples to the power transmission line is used to sense the changes in current in the transmission line 102 and feed it to the controller 604. The controller 604 then provides the necessary instructions to the converters 603 coupled to it. The sensor and power supply module 602 also extracts power from the transmission line to supply to the controller 604 and the other electronic control circuits of the module. This magnetic coupling requires no direct connection to the high voltage transmission line and/or cutting and splicing thereof, and therefore is better suited for a retrofit of existing transmission systems, and even for new installations, should be less costly to implement. The only consideration is the support and insulation for the injection module. In that regard, modules that are only magnetically coupled to the high voltage transmission line are not grounded, but allowed to electrically float with the respect to the transmission line so must be supported using the required insulative characteristics, though usually adequate support and insulation are already available at the support towers, provided the size and weight of the injection modules is appropriately chosen by design.

(18) FIG. 7 is a schematic illustration 700 of a long distribution line where the intelligent and self-aware injection modules 701 are distributed over the transmission line 102 at the towers 101 to monitor and control the impedance of the line and provide line balancing and power transfer control capability from the generators 103 to the load 104. These injection modules 701 can also be effectively used to reduce or eliminate the Ferranti effect by injecting a corrective inductance in the high voltage line to reduce or eliminate the {right arrow over (V.sub.L)} 404 voltage component in FIG. 4A which gives rise to the Ferranti effect. Instead or in addition, a corrective capacitance could be injected by the injection modules 701 which would reduce the transmission line current {right arrow over (I.sub.RL)} 310 charging capacitor C.sub.R 303 and thus reduce the current through and hence the voltage {right arrow over (V.sub.L)} 404 across the inductance L 305 (FIG. 3).

(19) As discussed earlier, concerning the phase diagram 400 in FIG. 4A, the Ferranti effect is produced when the load current on the transmission lines is very low, the load is removed, or the line is open-circuited. These scenarios result in the current of the high voltage transmission line comprising mainly the current in the distributed shunt capacitor of the high voltage transmission line. This capacitive current produces voltage drops in the distributed series inductors L 205 and the distributed resistors R 204 of the high voltage transmission line. The phasor diagram of FIG. 4A illustrates that due to the phase differences introduced by the capacitive current {right arrow over (I.sub.CR)} 309 flowing in the line inductance L 305, an additional voltage drop is produced, shown by the phasor {right arrow over (V.sub.L)} 404. This additional voltage drop is 180 degrees out of phase with the received voltage V.sub.R 207 at the receiving end of the transmission line. This combined with the inphase resistive drop {right arrow over (V.sub.R)} 403, in the line resistance R 304, produces the resultant Ferranti effect voltage vector {right arrow over (V.sub.S)}-{right arrow over (V.sub.R)} 401 that makes the magnitude of sending end voltage {right arrow over (V.sub.S)} 206 illustrated in FIG. 4A smaller than the magnitude of the voltage at the receiving end {right arrow over (V.sub.R)} 207 of FIG. 4A.

(20) Since the voltage rise is a distributed function that is cumulative over the length of the HV transmission line, it is possible to introduce corrective changes by the preferred method of injecting the correct voltage (impedance) values by the voltage/impedance injection modules distributed over the HV transmission line. Alternately the correction can be applied, as injected voltages to correct the cumulative effect over sections of the high voltage transmission line by using groups of impedance/voltage injection modules, at different points in the line. Both such corrections will be very effective in overcoming the Ferranti effect.

(21) FIG. 8 shows each of the distributed segments 801-1 and 801-2 of the HV transmission line 102. At least one injection module 701 is attached to or suspended from and used to provide a transmission line balancing capability. The distributed segments 801 of the HV transmission line are represented by the distributed impedance diagram 201 of FIG. 2. The injection modules 701 receive wireless control signals from the receiving substation, or from separate localized intelligent centers which themselves receive the needed information from the receiving substation (not shown). Since a long transmission line is involved, the transmission line length may exceed the capabilities of the wireless communication, though the needed control information may easily be sequentially relayed by the injection modules themselves, or by the localized intelligent centers previously referred to. In that regard, note that it is not a disturbance that is being corrected, but a characteristic of the transmission line itself. Consequently, the injection modules themselves, having a transmission line current sensing capability, can be programmed to use a default Ferranti effect correction when they sense the low transmission line current characteristic of an unloaded transmission line, which default correction can then be adjusted for any changes in transmission line characteristics due to weather, etc., based on the actual voltage measurements at the receiving end of the transmission line.

(22) Note also that the Ferranti effect is not a strong effect in comparison to other conditions sought to be corrected by the injection modules (line balancing, power factor correction, etc.), but is a cumulative effect of a long transmission line 102. Consequently, the number of injection modules used for overall transmission line control may easily exceed the number needed simply for correction of the Ferranti effect, in which case one might use an equally spaced subset of the available modules for this purpose.

(23) The injection modules are sometimes referred to as impedance/voltage injection modules, as the function of the modules for the present invention is the injection of an effect onto the transmission line with the proper phasing to achieve the desired result, specifically the diminishing or cancellation of the voltage {right arrow over (V.sub.L)} 404 as shown in FIG. 4B. The injection might be considered an injection of an opposing voltage {right arrow over (V.sub.Cor)} 402, or alternatively, the injection of a cancelling inductance, that counteract the line inductance L 305. Any power needed for the injection itself is also taken from the transmission line prior to the injection through the magnetic coupling from and to the transmission line.

(24) Even though the invention disclosed is described using specific implementations, circuits, and components, it is intended only to be exemplary and non-limiting. The practitioners of the art will be able to understand and modify the same based on new innovations and concepts, as they are made available. The invention is intended to encompass these modifications.