DYNAMIC VAR COMPENSATION SYSTEM AND METHOD FOR AC FURNACE
INTRODUCTION AND BACKGROUND
This invention relates to an electrically operable furnace and more particularly to an electrical power supply for an AC furnace and a method of controlling a furnace parameter, such as power factor.
It is well known to use capacitors on a primary side of a furnace step- down transformer of an AC furnace system to improve the power factor of the system. However, due to a reactive component of the furnace load as seen by the transformer, the furnace still operates at a lagging power factor of typically between 70% and 85% . Hence, these capacitors do not improve the supply capacity of the furnace power supply system or contribute to the furnace production capacity.
OBJECT OF THE INVENTION
Accordingly, it is an object of the present invention to provide an alternative furnace power supply system, associated method of controlling a power factor and electrically operable furnace with which the applicants believe the aforementioned disadvantages may at least be alleviated or which may provide a useful alternative for the known
furnace power supply systems, methods of controlling power factor and electrically operable furnaces.
SUMMARY OF THE INVENTION
According to the invention there is provided a furnace power supply system comprising:
at least one furnace power supply voltage step-down transformer for stepping down a first voltage to a second voltage;
a secondary winding of the voltage step-down transformer being connectable to at least one electrode of the furnace;
a compensation system connected to the secondary winding of the step-down transformer, the compensation system comprising a plurality of capacitors in respective parallel branches, at least some of the branches comprising a respective switch element; and
a controller for operating the switch elements; the controller comprising an input for a signal representative of a power factor seen by the secondary winding of the step-down transformer and the controller being configured to open and close the switch elements in
response to the signal, thereby to control the power factor.
The switch elements may be solid-state switch elements.
The controller may be configured to operate the switch elements at suitable times, so as to reduce transient effects over the capacitors. For example, the controller may be configured to operate the switch elements when the instantaneous value of the second voltage is equal to the voltage across the capacitors.
The controller may be configured automatically to generate switching signals to operate selected switch elements, thereby to connect or disconnect capacitors selected from the plurality of capacitors to or from the secondary winding, thereby to improve the power factor in real time.
The controller may be configured to operate the switch elements thereby to connect or disconnect harmonic filter elements comprising at least some of the capacitors and/or reactors and/or resistors to or from the secondary winding, thereby to filter out unwanted harmonics.
Hence, a reactor, such as a coil and/or a resistor may also be connected in at least some of the branches.
The first voltage may be between 1 1 kV and 33kV and the second voltage may be between 200V and 600V.
A first connection may be provided between the secondary winding of the at least one voltage step-down transformer and the at least one electrode and the first connection may comprise a high current furnace bus tube.
A second connection may be provided between the secondary winding of the at least one voltage step-down transformer and the compensation system and the second connection may comprise a high current connection.
The compensation system may comprise a three-phase system. In other embodiments the compensation system may comprise an arrangement of three single phase systems.
Also included within the scope of the present invention is an AC furnace system comprising a furnace power supply system as herein defined and/or described.
Yet further included within the scope of the present invention is a method of controlling a power factor in an AC furnace, the method comprising the steps of:
utilizing a compensation system connected to a secondary winding of a power supply step-down transformer for stepping down a first supply voltage to a second lower voltage, the second winding being connected to at least one electrode of the furnace;
receiving a signal representative of a power factor as seen by the secondary winding of the step-down transformer; and
causing the compensation system to connect capacitors to the secondary winding to control the power factor in real time.
BRIEF DESCRIPTION OF THE ACCOMPANYING DIAGRAMS
The invention will now further be described, by way of example only, with reference to the accompanying diagrams wherein:
figure 1 is a basic circuit diagram of a furnace power supply system according to the invention;
figure 2 is a basic diagram of a first embodiment of the furnace and power supply system;
figure 3 is a similar diagram of a second embodiment of the furnace and power supply system;
figure 4 is a similar diagram of a third embodiment of the furnace and power supply system; and
figure 5 is a vector diagram illustrating an improvement in active power delivered to the furnace and hence an improvement in capacity of the furnace.
DESCRIPTION OF A PREFERRED EMBODIMENT OF THE INVENTION
A furnace power supply system according to the invention for an electrically operable AC furnace 1 6 is generally designated by the reference numeral 1 0 in the figures.
Referring to figure 1 , the furnace power supply system 1 0 comprises at least one furnace power supply voltage step-down transformer 1 2 for stepping down a first voltage V1 to a second voltage V2. A secondary winding 1 2.2 of the step down transformer 1 2 is connectable to at least one electrode 1 4 of the furnace 1 6. A dynamic
VAR compensation system 1 8 is connected to the secondary winding 1 2.2 of the step-down transformer 1 2. The compensation system comprises a plurality of capacitors 20.1 to 20. n in parallel branches 22.1 to 22. n in a bank 20. At least some of the capacitors in the bank are in series with a respective switch element. In some embodiments, the switch elements form part of a switching module 24.
In some embodiments, at least some of branches 22.1 to 22. n comprise one capacitor 20.1 to 20. n and a respective switch element 24.1 to 24.2 in series. In other embodiments, at least some branches comprise serial or parallel groups of capacitors connected in series with a respective switch element for the branch.
In the embodiment shown, the switch elements 24.1 to 24. n are solid- state switch elements.
Also in the embodiment shown, a reactor in the form of a coil 26.1 to 26. n is connected in at least some of the branches 22.1 to 22. n.
The VAR compensation system 1 8 comprises a controller 28 for generating switching signals on output lines 28.1 to 28. n to operate
the switch elements 24.1 to 24. n, thereby to connect or disconnect the capacitors 20.1 to 20. n to or from the secondary winding 1 2.2.
The controller 28 has an input 29 for a signal representative of a power factor as seen by the secondary winding of the step-down transformer, to be controlled. The controller is configured to operate selected ones of the switch elements 24.1 to 24. n, to connect or disconnect capacitors selected from the plurality of capacitors to or from the secondary winding thereby to improve the power factor of the load 1 4 as seen by the secondary winding 1 2.2 of the step-down transformer in real time. Optimally, in addition, the switch elements 24.1 to 24. n connect or disconnect branches to or from the secondary winding thereby to filter out unwanted harmonics caused by the at least one electrode 1 4.
Hence, a signal or data relating to the power factor as seen by the secondary winding is supplied to the controller 28 via input 29 and the controller 28 is configured, by means of the high speed switch elements 24.1 to 24. n, to add or subtract capacitors from the circuit connected to the secondary winding, thereby, in real time, reducing the reactive load and hence power factor and optionally tuning harmonic filters on the secondary side.
The controller is preferably configured to cause the switch elements 24.1 to 24. n to operate at suitable times, to reduce transient effects over the capacitors. The first voltage may be between 1 1 kV and 33kV and the second voltage may be between 200V and 600V.
The connection 30 between the secondary winding 1 2.2 of the at least one step-down transformer and the at least one electrode 1 4 comprises high current furnace bus tubes.
The connection 32 between the secondary winding of the at least one step-down transformer and the dynamic VAR system 1 8 comprises a high current connection.
In figure 2, there is shown a first embodiment of the furnace system according to the invention. The furnace 1 6 comprises three electrodes 1 4.1 , 1 4.2 and 1 4.3. Three similar furnace power supply step-down transformers 1 1 2.1 to 1 1 2.3 are provided to step down a first and high supply voltage Vi (typically 1 1 kV to 33kV) to a second and lower furnace operating voltage V2 (typically 200V to 600V). Electrodes 1 4.1 and 1 4.2 are connected in known manner by high current
furnace bus tubes 30 to the secondary winding 12.2 of step-down transformer 112.1. In the same manner, electrodes 14.2 and 14.3 are connected to the secondary winding 12.2 of the transformer 112.2 and electrodes 14.3 and 14.1 to the secondary winding of transformer 112.3. Single phase capacitor banks 20.1 to 20.3 of a dynamic VAR system 18 as hereinbefore described are connected to the secondary windings 12.2 of the transformers 112.1 to 112.3 respectively.
The embodiment in figure 3 is similar to the embodiment of figure 2, except that the furnace comprises six electrodes 14.1 to 14.6, of which electrodes 14.1 and 14.2, 14.3 and 14.4, and 14.5 and 14.6 are connected to the secondary windings of the voltage step-down transformers 112.1 to 112.3, respectively. Single phase banks 20.1 to 20.3 of a dynamic VAR system 18 as hereinbefore described are connected to the secondary windings 12.2 of the transformers 112.1 to 112.3 respectively.
The embodiment in figure 4 comprises a three-phase furnace voltage step-down transformer 12. Each of the phases of the secondary winding 12.2 is connected to a respective electrode 14.1 to 14.3 of the furnace 16. A three-phase dynamic VAR system 18, generally
similar to the dynamic VAR systems as hereinbefore described, is connected to the secondary of the transformer 1 2.
The vector diagram in figure 5 illustrates that for an apparent power S for the furnace step-down transformer 1 2 (shown in figure 1 ) of say 63 MVA, with a prior art power factor Φ1 of between 70% and 85% as referred to in the introduction of this specification, there is an active power component P1 of about 50.3 MW and a reactive power component of Q1 . The aforementioned capacitor arrangements of the dynamic VAR system 1 8 reduce the reactive component as seen by the transformer 1 2 continually and in real time to Q2, thereby improving the power factor to Φ2 of about 96%, so that for the same apparent power S, additional active power (up from P1 to P2 of about 56.7 MW) is supplied to the furnace 1 6, thus increasing the production capacity of the furnace.
Hence, it is believed that while utilizing existing furnace transformers, more active power is supplied to the furnace, thus resulting in improved production capacity. Secondary or electrode voltage varies in furnaces, mainly due to substantial changes in the reactive load. By reducing the reactive component on a real time basis as hereinbefore described, it is expected that a more constant voltage may be
maintained at the electrodes. Furthermore, the power factor is improved on the secondary side of the furnace transformer 1 2, thus increasing the capacity of the existing power supply to provide active power to the furnace and improving the power factor on the primary side as well and hence reducing electricity bills. Conventional switching of capacitor banks normally cause transients, whereas it is believed that with a dynamic VAR system 1 8 as herein described, transients may be reduced, thus inhibiting degradation of furnace transformers. Still furthermore, furnaces, such as open arc scrap melters, generate high levels of unwanted harmonics which are conventionally filtered out with filter banks on the primary side of the furnace transformer 1 2. With the system according to the invention, the dynamic VAR system 1 8 may comprise harmonic filter components and hence it is believed that the total harmonic distortion (THD) may be reduced on the secondary side of the furnace transformer 1 2, thereby reducing furnace system losses.