Voltage sag and over-voltage compensation device with...

Electrical transmission or interconnection systems – With line drop compensation

Reexamination Certificate

Rate now

  [ 0.00 ] – not rated yet Voters 0   Comments 0

Details

C307S130000, C361S091700

Reexamination Certificate

active

06750563

ABSTRACT:

TECHNICAL FIELD
The present invention relates generally to the field of electric distribution power systems and, more particularly, relates to a voltage sag and over-voltage compensation device for an AC electric power distribution system employing a pulse-width modulated transformer.
BACKGROUND OF THE INVENTION
Voltage sags and over-voltage conditions occasionally occur on AC power distribution systems for a variety of reasons, such as high resistance faults in the distribution system, fault clearing, switching large loads characterized by arcing during connection or disconnection of the load, other types of transient circuit overloading (e.g., dynamic disturbances), high load inductance during unusually heaving load periods, and line capacitance during unusually light load periods. Although these voltage conditions may be short lived, such as a few cycles in a 50 or 60 Hertz electric power system for transient disturbances and fault clearing events, they can nonetheless cause sensitive loads, such as computer systems and manufacturing operations, to experience equipment damage and, in some cases, to drop off line. Therefore, devices that compensate for these voltage sags and over-voltage conditions, so that the loads receive an uninterrupted supply of the intended line voltage, serve an important function for these types of sensitive loads.
Certain conventional approaches to AC voltage compensation use traditional inverter technology, which rectifies the AC line power into DC power and stores the DC energy, typically in capacitors, batteries, or a flywheel during normal system operations. Then, during a voltage sag, the sag supporter device inverts the stored DC energy into AC power and delivers this power through a series-connected transformer to supply the missing voltage. This conventional inverter approach is complex and requires a large number of power switching elements to create the replacement voltage profile. The switching elements are relatively expensive and render the sag supporter financially infeasible for many applications. In addition, the duration of the available voltage support is limited by the amount of energy that can be stored prior to the voltage sag, and can therefore require large storage devices. Large storage devices can significantly increase the size of the device, often making pole-mounted configurations impractical. Alternatively, the circuitry required to repeatedly discharge and charge capacitors during the voltage sag condition presents complex control and timing challenges associated with continually recharging the capacitors to the proper level, and further increases the cost and sophistication of the device. In addition, the presence of the series-connected transformer in the power line during normal circuit operation causes significant power losses, even when voltage support is not required.
In another conventional approach, a tap switching series-connected transformer, often called a voltage regulator, may be used to compensate for voltage sag conditions. However, the large number of windings and switching elements required to provide a range of voltage sag compensation increases the cost of the voltage regulator and, in any event, limits the device to providing a discrete number of voltage steps in the output power supply. In addition, due the implementation time required for tap-changing voltage correction, these systems are ill suited to following fast changing voltage sag or over-voltage events, which typically occur when the cause of the voltage sag or over-voltage event involves a fault or switching event characterized by arcing. Arcing, by it's very nature, is erratic in behavior and changes quickly during the event as attachment points move around. Again with this type of device, the presence of a series-connected transformer in the power line during normal operations causes significant power losses.
Transient over-voltage conditions caused by the tap switching series-connected transformer presents another significant disadvantage of the tap-switching voltage regulator approach. This typically occurs when a breaker or fuse clears a fault causing the voltage sag, which abruptly returns the system to normal voltage. This typically occurs at a zero-current condition, which is followed by the series-connected transformer boosting the voltage on its output well above its normal level for approximately 8 milliseconds until the transformer can be returned to its normal setting, which usually occurs at the next zero-current condition. This “current-zero switching” limitation occurs with these devices because they typically employ thyristor switching elements, which can only switch during zero-current conditions. Thus, notwithstanding multiple winding ratios and multiple switching elements, these systems still impose a significant over-voltage on the load at the conclusion of many voltage sag events.
Therefore, there is a need in the art for a compact, cost effective voltage sag and over-voltage compensation device that does not routinely impose over-voltage conditions on the loads they are designed to protect. There is also a need for a voltage sag and over-voltage compensation device that does not require a large number of switching devices, large power storage devices, or a series-connected transformer in the power line during normal operation of the circuit.
SUMMARY OF THE INVENTION
The present invention meets the needs described above in a voltage sag and over-voltage compensation device employing a pulse-width modulated transformer, which may be an autotransformer or a step-up transformer, such as a two-winding transformer. In various embodiments of the present invention, the modulating switch may be connected in series with the transformer, or the modulating switch may be connected in parallel with one winding of the transformer. All of these configurations may be operated in different modes to accomplish the objectives of the invention. In addition, the device preferably operates at AC electric power distribution system voltages, but may be designed to operate at other voltage levels.
The voltage sag and over-voltage compensation device employing a pulse-width modulated transformer significantly improves over conventional inverter technology in that no energy storage devices are required. The present invention also significantly improves over conventional tap-switching transformer technology in that no over-voltage is imposed on the load when a voltage sag event is over. Moreover, the technology of the present invention is much simpler than prior approaches for AC voltage compensation in that it reduces the number of active switching elements and uses well developed transformer technology as the basic design element. This advantageously allows switching to occur at higher voltages with lower currents than occurs in prior designs. In addition, a single switching frequency with a single pulse-width for any given voltage sag or over-voltage condition makes the control system for the present invention relatively simple to design and implement. The end result is a comparatively uncomplicated design, which exhibits lower cost and higher reliability, while providing equivalent or improved functionality in comparison to prior art voltage compensation technologies.
Generally described, the present invention includes a voltage sag and over-voltage compensation device that receives electric power from an AC power source oscillating at a system frequency, adjusts the voltage of the power, and delivers a corresponding voltage-corrected AC power supply to a connected load. The voltage sag and over-voltage compensation device includes a transformer and a modulating switch operable between an open configuration and a closed configuration for selectively connecting the AC power source to the transformer. The device also includes a control unit for selectively gating the modulating switch between the open configuration and the closed configuration multiple times per cycle of the system frequency to generate the voltage-corrected AC power su

LandOfFree

Say what you really think

Search LandOfFree.com for the USA inventors and patents. Rate them and share your experience with other people.

Rating

Voltage sag and over-voltage compensation device with... does not yet have a rating. At this time, there are no reviews or comments for this patent.

If you have personal experience with Voltage sag and over-voltage compensation device with..., we encourage you to share that experience with our LandOfFree.com community. Your opinion is very important and Voltage sag and over-voltage compensation device with... will most certainly appreciate the feedback.

Rate now

     

Profile ID: LFUS-PAI-O-3341919

  Search
All data on this website is collected from public sources. Our data reflects the most accurate information available at the time of publication.