The present disclosure relates to a technique for lowering inrush current to an uninterruptible power supply which employs a transformer.
An uninterruptible power supply is an electrical apparatus that provides emergency power to a load when the input power source fails. Typically, the UPS includes a rectifier that converts AC input power to DC power and an inverter that converts the DC power from the rectifier back to AC power. In some instances, an input transformer may be connected between the input power source and the rectifier. When a transformer is first energized, an inrush current many times larger than the rated transformer current can flow into the transformer for several cycles. Such large inrush currents can damage certain circuit components and require additional design consideration as well as associated cost to counter the effects of any large inrush currents.
One technique for lowering inrush current in a UPS with a transformer is presented in this disclosure.
This section provides background information related to the present disclosure which is not necessarily prior art.
This section provides a general summary of the disclosure, and is not a comprehensive disclosure of its full scope or all of its features.
A power supply system is provided which implements a technique for lowering inrush current. The system includes: a transformer with a primary winding is configured to receive an AC input signal from a power supply; a switch electrically coupled between the power supply and the primary winding of the transformer; an active rectifier electrically coupled between the secondary winding of the transformer and a DC bus; a precharge circuit electrically coupled between the power supply and the DC bus and a controller interfaced with the precharge circuit and the active rectifier. The precharge circuit applies a DC voltage to the DC bus in response to a control signal.
The controller determines when AC voltage at the primary winding of the transformer equals the AC input signal and closes the switch in response to a determination that the AC voltage at the primary winding of the transformer substantially equals the AC input signal. The controller further provides the control signal to the precharge circuit during a startup phase and discontinues providing the control signal to the precharge circuit when the switch is closed. The controller also operates the active recitifier as an inverter during the startup phase.
In another aspect, a method is presented for lowering inrush current to an uninterruptible power supply. The method includes: providing a transformer, where the primary winding is configured to receive an AC input signal from a power supply; opening a switch interposed between the power supply and the primary winding of the transformer during a startup phase; applying an AC voltage to the secondary winding of the transformer, where magnitude of the AC voltage is less than magnitude of the AC input signal; increasing the magnitude of the AC voltage over time until the magnitude of the AC voltage on primary winding of the transformer equals magnitude of the AC input signal; determining whether the magnitude of the AC voltage on primary winding of the transformer equals the magnitude of the AC input signal; and closing the switch in response to a determination by the controller that the magnitude of the AC voltage equals the magnitude of the AC input signal.
Further areas of applicability will become apparent from the description provided herein. The description and specific examples in this summary are intended for purposes of illustration only and are not intended to limit the scope of the present disclosure.
The drawings described herein are for illustrative purposes only of selected embodiments and not all possible implementations, and are not intended to limit the scope of the present disclosure.
Corresponding reference numerals indicate corresponding parts throughout the several views of the drawings.
Example embodiments will now be described more fully with reference to the accompanying drawings.
The UPS converter 13 further includes a rectifier 4, an inverter 6, a DC/DC converter 18 and a secondary power source 9, such as battery. The rectifier 4 converts the AC input from an AC signal to a DC signal; whereas, the inverter 6 converts a DC signal to an AC signal. The DC/DC converter 18 interfaces the battery 9 to the main DC bus. The inverter 6 is configured to receive an input signal from either the rectifier 4 or the battery 9. In normal operation, the rectifier 4 supplies the DC signal to the inverter 6 and the DC/DC converter 18 provides a charging current for the battery 9. If the primary power source 16 is not available or the rectifier cannot otherwise provide enough power, the DC/DC converter switches from a charging mode to a discharging mode and the battery 9 supplies the input signal to the inverter 6. Such converter arrangements are known in the art.
The controller 15 monitors the operating conditions of the UPS 10 and controls the bypass switch 11 and the UPS switch 12 depending on the selected mode of operation and the operating conditions. In an exemplary embodiment, the controller 15 is implemented as a microcontroller. It should be understood that the logic for the control of UPS 10 by controller 15 can be implemented in hardware logic, software logic, or a combination of hardware and software logic. In this regard, controller 15 can be or can include any of a digital signal processor (DSP), microprocessor, microcontroller, or other programmable device which are programmed with software implementing the above described methods. It should be understood that alternatively the controller is or includes other logic devices, such as a Field Programmable Gate Array (FPGA), a complex programmable logic device (CPLD), or application specific integrated circuit (ASIC). When it is stated that controller 15 performs a function or is configured to perform a function, it should be understood that controller 15 is configured to do so with appropriate logic (such as in software, logic devices, or a combination thereof).
A switch 21 is electrically coupled between the primary power supply 16 and the primary winding of the transformer 22. In one embodiment, the switch 21 is further defined as a contactor that is interfaced with the controller 15. It is understood that relays as well as other types of switches may be used in place of the switch 21.
A DC bus precharge circuit 23 is electrically coupled between the power supply and the DC bus. During a startup phase, the precharge circuit 23 is used to apply a DC voltage to the DC bus. In an example embodiment, the transformer 22 may function as a step down, for example from 230 volts to 180 volts. In the example embodiment, the precharge circuit 23 includes a switch, a resistor, and a rectifier coupled in series between the power supply and the DC bus. In an alternative embodiment, the precharge circuit 23 may be supplied input power by another power source, such as the backup battery 9 of the UPS. Other arrangements for the precharge circuit 23 also fall within this scope of this disclosure.
To avoid an inrush current to the transformer 22, a controlled voltage is applied to the secondary side of the transformer 22 during a startup phase. Before the system is energized, switch 21 is open and thus the transformer 22 is not energized. During a startup phase, the controller 15 provides a control signal to the precharge circuit 23 and the precharge circuit 23 in turn supplies a DC voltage to the DC bus. Specifically, the DC voltage is supplied to the output side of the active rectifier 4. An extra DC source 25 can also supply voltage via a switch 26 to the DC bus during the startup phase. In one embodiment, the extra DC source is the battery from the UPS. In other embodiments, the extra DC source is another rectifier that is connected to the DC bus. The extra DC source may be needed to perform a voltage ramp at secondary side of the transformer 22 as further described below.
Additionally, the controller 15 operates the active rectifier 4 as an inverter during the startup phase. In one embodiment, the active rectifier 4 includes at least one transistor. During the startup phase, the controller 15 biases the transistor of the active rectifier 4 so as to generate an AC voltage at an input of the active rectifier 4. Because the input of the active rectifier 4 is coupled to the secondary winding of the transformer 22, this voltage magnetizes the core of the transformer 22. When the switch 21 is subsequently closed and power is applied to the primary side of the transformer 22, the core is already magnetized such that the inrush current is minimized or eliminated.
In the example embodiment, the controller 15 modulates the active rectifier 4 properly to generate a sinusoidal voltage at the primary side of the transformer 22. More specifically, the controller modulates the active rectifier 4 so that the sinusoidal voltage at the primary side of the transformer 22 matches, in terms of phase and amplitude, the phase and amplitude of the input voltage from the primary power supply 16.
Once the controller 15 determines that the voltage on the primary side of the transformer matches the input voltage from the primary power supply 16, the controller 15 closes switch 21, thereby completing the startup phase. It should be understood that matching in this context means that the magnitudes are equal within a tolerance, such as +/−5%, and their phases are in synch within a tolerance, such as +/−three degrees. Concurrently therewith, the controller 15 discontinues supply a control signal to the precharge circuit 23 and the precharge circuit 23 no longer supplies a DC voltage to the DC bus. Additionally, the controller 15 ceases to operate the active rectifier 4 as an inverter and begins operating it normally as a rectifier. That is, the controller 15 biases the transistors of the active rectifier 4 to convert the AC input signal at its input to a DC voltage at its output.
Next, the controller 15, in conjunction with the precharge circuit 23, generates a signal at 32 that magnetizes the core of the transformer 22. To do so, the controller 15 operates the active rectifier 4 as an inverter. It is important to increase magnetizing flux from zero to a steady-state without having the transformer saturate. In one embodiment, the magnitude of the AC voltage applied to the secondary winding of the transformer is initially less than the magnitude of the AC voltage from the power supply and close to zero. The magnitude of the AC voltage is increased gradually over time until the magnitude of the AC voltage on primary winding of the transformer reaches the magnitude of the AC input voltage as seen in
After the startup phase (i.e., after switch 21 is closed), the controller 15 deactivates the precharge circuit 23 at 36, for example by opening the second switch in the precharge circuit path. The controller 15 also ceases operating the active rectifier 4 as an inverter and resumes normal operation of the rectifier at 37. That is, the controller 15 biases the transistors of the active rectifier 4 such that it converts an AC voltage at its input to a DC voltage at its output. After switch 21 is closed, the extra DC source may be decoupled from the DC bus or, in some cases, it may remain connected to the DC bus. It is to be understood that only the relevant steps of the methodology are discussed in relation to
In the example embodiment, the active rectifier 4 is comprised of a plurality of transistors. Specifically, the transistors are arranged as a 3-level T-type neutral point clamp. Other types of arrangements for the rectifier fall within the scope of this disclosure.
In the example embodiment, the DC bus precharge circuit 23 is implemented by a precharge switch 44 coupled in series with a rectifier 46. In this example, the precharge switch 44 is further defined as a relay and the rectifier 46 is a diode bridge although other arrangements are contemplated as well. The precharge switch 44 is controlled by the controller 15 during the startup phase and after the startup phase in the manner described above. A resistor 45 may be electrically coupled between the precharge switch 44 and the rectifier 46. An auxiliary transformer 44 may also be used to electrically couple the precharge circuit 23 to the primary power supply.
In this embodiment, the battery 9 from the UPS serves as an extra DC source during the startup phase. The battery 9 is coupled via a user actuated switch 48 to an output side of the active rectifier 4. The operator is prompted to close the switch 48 once the precharge has been activated. In this way, the battery 9 can supply part of the energy needed to magnetize the transformer during the startup phase. It is understood that other DC source may be integrated into the system within the broader aspects of this disclosure.
The foregoing description of the embodiments has been provided for purposes of illustration and description. It is not intended to be exhaustive or to limit the disclosure. Individual elements or features of a particular embodiment are generally not limited to that particular embodiment, but, where applicable, are interchangeable and can be used in a selected embodiment, even if not specifically shown or described. The same may also be varied in many ways. Such variations are not to be regarded as a departure from the disclosure, and all such modifications are intended to be included within the scope of the disclosure.