 UNINTERRUPTED POWER SUPPLY AND METHOD OF OPERATION OF AN UNINTERRUPTED POWER SUPPLY
专利摘要:
power supply control systems and methods for operating an uninterruptible power supply are provided. the uninterruptible power supply can include a rectifier that has a transistor and an inductor. the uninterruptible power supply can also include a controller. a current sensor may be configured to sense inductor current and provide a sensed inductor current value to the controller to generate a current error value and to generate a pulse width modulation control signal based in part , at the current error value. the controller can apply the pulse width modulation control signal to the transistor to adjust a switching frequency of the transistor. 公开号:BR112012000193B1 申请号:R112012000193-0 申请日:2010-05-21 公开日:2021-08-17 发明作者:Michael J.Ingemi;Damir Klikic 申请人:American Power Conversion Corporation; IPC主号:
专利说明:
Background of the Invention Field of Invention [0001] At least one embodiment of the present invention relates generally to the control of an uninterruptible power supply input circuit. Related Technique Discussion [0002] Rectifiers and other non-linear loads distort the current drawn from a source, which decreases the power factor of various power distribution systems and reduces their efficiency. Reactive elements in these systems can also create harmonic noise when switching between on and off states and at some operating frequencies. Rectifiers that operate inefficiently consume large amounts of energy from one source, increasing power supply costs, and can become audible during severe load conditions, decreasing commercial viability. Invention Summary [0003] At least one aspect pertains to an uninterruptible power supply that includes an input circuit that has a first transistor, a second transistor and an inductor. The uninterruptible power supply also includes a controller having a digital signal processor and a field-programmable port array. The controller is coupled to the input circuit to sense inductor current and to provide a sensed inductor current value to the digital signal processor. The controller may apply a pulse width modulation control signal to one of the first transistor and the second transistor to adjust a switching frequency of one of the first transistor and the second transistor. [0004] At least one aspect relates to a method of operating an uninterruptible power supply including an input circuit and a controller, the input circuit having a first transistor, a second transistor and an inductor, and the controller having a digital signal processor and an array of field-programmable gates. An inductor current from the input circuit is detected and its value is provided to the digital signal processor, which can generate a current error value based, in part, on the detected inductor current value. The method can provide the current error value to the field-programmable gate array, which can generate a pulse width modulation control signal based in part on the current error value. The method can apply the pulse width modulation control signal to one of the first transistor and the second transistor to control a switching frequency of one of the first transistor and the second transistor. [0005] At least one aspect pertains to an uninterruptible power supply having an input circuit. The input circuit includes a first transistor, a second transistor and an inductor. A controller having a digital signal processor and field-programmable gate array is coupled to the input circuit to sense inductor current and provide a sensed inductor current value to the digital signal processor. The uninterruptible power supply further includes means for applying a pulse width modulation control signal to one of the first transistor and the second transistor to adjust a switching frequency of one of the first transistor and the second transistor. [0006] At least one aspect refers to a system for distributing energy to a load. The system includes an input circuit with a first transistor, a second transistor and an inductor. The system also includes a controller having a digital signal processor and a field-programmable gate array coupled to the input circuit to sense inductor current and provide a sensed inductor current value to the digital signal processor. The controller can apply a pulse width modulation control signal to one of the first transistor and the second transistor to set a switching frequency of one of the first transistor and the second transistor, and the controller can apply an output voltage load. [0007] In some embodiments, the digital signal processor can generate a current error value based in part on the detected inductor current value and can provide the current error value to the field programmable gate array. The field-programmable gate arrangement can generate the pulse width modulation control signal based in part on the current error value. [0008] In at least one embodiment, the first transistor can be part of a first boost converter circuit (boost), and the second transistor is part of a second boost converter circuit. The input circuit may include a three-phase rectifier and the controller may apply the pulse width modulation control signal to the first transistor to switch an operating mode of the first boost converter circuit between fixed frequency continuous and quasi-discontinuous operating modes. of variable frequency. The controller may apply a second pulse width modulation control signal to the second transistor to switch an operating mode of the second boost converter circuit between continuous fixed frequency and quasi-discontinuous variable frequency operating modes. [0009] In some embodiments, the first boost converter circuit can operate in the quasi-discontinuous variable frequency operation mode, and wherein the second boost converter circuit simultaneously operates in the fixed frequency continuous operation mode. In various embodiments, the controller can apply the pulse width modulation control signal to one of the first transistor and the second transistor to alternate an operating mode of one of the first boost converter circuit and the second boost converter circuit between the Continuous fixed-frequency and quasi-batch variable-frequency operating modes. In some embodiments, at least one of the first transistor and the second transistor may switch to an on state when the sensed inductor current value drops substantially to zero. [0010] In some embodiments, the three-phase rectifier can be configured for operation during a line cycle having a first phase voltage, a second phase voltage, and a third phase voltage, and the controller can switch the operating mode of a between the first boost converter circuit and the second boost converter circuit during a part of the line cycle, where each of the first phase voltage, the second phase voltage, and the third phase voltage is mutually exclusive. The digital signal processor can generate a voltage error value and provide the voltage error value to the field-programmable gate array, and the field-programmable gate array can generate the pulse width modulation control signal with based in part on the voltage error value. In at least one embodiment, the input circuit can include a three-phase rectifier that has a first inductor, a second inductor, and a third inductor, and the detected inductor current can include current from at least two of the first, second, and third inductors. [0011] Other aspects, embodiments and advantages of these aspects and exemplary embodiments will become apparent from the following detailed description, considered in conjunction with the accompanying drawings, illustrating the principles of the invention by way of example only. It is to be understood that the foregoing information and the following detailed description include illustrative examples of various aspects and embodiments, and are intended to provide an overview or framework for understanding the nature and characteristics of the claimed aspects and embodiments. The drawings, together with the rest of the specification, serve to explain the principles and operations of the aspects and embodiments described and claimed. Brief Description of Drawings [0012] The attached drawings are not drawn to scale. In the drawings, each identical or nearly identical component that is illustrated in several figures is represented by a like number. For clarity, not all components can be identified on all drawings. In the drawings: Figure 1 is a functional block diagram representing an uninterruptible power supply according to an embodiment of the invention; Figure 2 is a schematic diagram representing an input circuit according to an embodiment of the invention; Figure 3 is a functional block diagram representing an uninterruptible power supply according to an embodiment of the invention; Figure 3A is a functional block diagram representing an uninterruptible power supply according to an embodiment of the invention; Figure 4 is a schematic diagram representing an uninterruptible power supply that includes a three-phase rectifier in accordance with an embodiment of the invention; Figure 4A is a schematic diagram representing an uninterruptible power supply that includes a three-phase rectifier in accordance with one embodiment of the invention; Figure 4B is a schematic diagram representing an uninterruptible power supply that includes a three-phase rectifier in accordance with one embodiment of the invention; Figure 4C is a schematic diagram representing an uninterruptible power supply that includes a three-phase rectifier in accordance with one embodiment of the invention; Figure 4D is a schematic diagram representing an uninterruptible power supply that includes a three-phase rectifier in accordance with one embodiment of the invention; Figure 5 is a graph representing a three-phase line cycle according to an embodiment of the invention; Figure 6 is a schematic diagram representing a controller in accordance with an embodiment of the invention; Figure 7 is a graph representing inductor current in an input circuit operating in quasi-batch mode during a line cycle in accordance with one embodiment of the invention; Figure 8 is a graph representing inductor current in an input circuit operating in quasi-batch mode during a line cycle in accordance with one embodiment of the invention; Figure 9 is a graph representing an input circuit operating in quasi-discontinuous mode of operation in accordance with an embodiment of the invention; Figure 10 is a graph representing the input circuit switching frequency during a line cycle in accordance with an embodiment of the invention; Figure 11 is a graph representing the switching frequency of the input circuit during a line cycle according to an embodiment of the invention; Figure 12 is a graph representing the input circuit switching frequency during a line cycle in accordance with an embodiment of the invention; and Figure 13 is a flowchart illustrating a method of operating an uninterruptible power supply in accordance with an embodiment of the invention. Detailed Description [0013] The systems and methods described in this document are not limited in their application to the construction details and arrangement of components presented in the description or illustrated in the drawings. The invention can encompass other embodiments and can be practiced or carried out in various ways. Furthermore, the phraseology and terminology used herein is for the purpose of description and should not be considered limiting. The use of "including", "comprising", "having", "containing", "involving" and its variations is intended to cover the items listed below and their equivalents, as well as additional items. [0014] Various aspects and embodiments relate to control of operating frequency, power factor correction and total harmonic distortion of systems, uninterruptible power supplies and methods of distributing power to a load. As discussed below, for example, the system can include an input circuit that has a transistor and an inductor. The system can also include a controller. A current sensor may be configured to detect inductor current and to provide a sensed inductor current value to the controller to generate a current error value based, in part, on the detected inductor current and to generate an inductor signal. pulse width modulation control based in part on the current error value. The controller may apply the pulse width modulation control signal to the transistor to adjust a transistor switching frequency to provide desired circuit operating frequencies, power factor correction, and total harmonic distortion. [0015] Figure 1 is a functional block diagram of an uninterruptible power supply (UPS) 100 according to an embodiment. In one embodiment, the UPS 100 supplies power to at least one load 105. The UPS 100 may also include at least one input circuit 110, such as a rectifier (e.g., a buck-boost converter circuit). which may also be referred to as a positive converter and a negative converter, or universally as a boost converter circuit or simply boost converter), at least one inverter 115, at least one battery 120 and at least one controller 125. In one embodiment, a The UPS 100 includes AC input lines 130 and 135 to couple respectively to the line and neutral of an incoming AC power source. The UPS 100 may also include outputs 140 and 145 to provide an output and neutral line for the load 105. [0016] In a line mode of UPS 100 operation, in one embodiment under the control of the controller 125, the input circuit 110 receives input AC voltage from inputs 130 and 135 and provides positive and negative output DC voltages on the lines outputs 150 and 155 with respect to common line 160. In a battery mode of UPS 100 operation, for example, after loss of input AC power, input circuit 110 can generate DC voltages from battery 120. In this example, common line 160 can be coupled to input neutral line 135 and output neutral line 145 to provide a continuous neutral across UPS 100. Inverter 115 receives DC voltages from input circuit 110 and provides output AC voltage on the lines 140 and 145. [0017] Figure 2 is a schematic diagram representing the input circuit 110 according to an embodiment of the invention. In one embodiment, input circuit 110 includes input diodes 205 and 210, input capacitors 215 and 220, relays 225 and 230, inductors 235 and 240, lift transistors 245 and 250, diode 255, output diodes 260 and 265 and output capacitors 270 and 275. [0018] As illustrated in Figure 2, the input circuit 110 is configured in a line operating mode, in which relays 225 and 230 are configured to couple the AC input lines 130 and 135 with the inductors 235 and 240, such that positive and negative rectified voltages are respectively provided to inductors 235 and 240. In one embodiment, inductor 235 operates in conjunction with transistor 245 and output diode 260 as a positive boost converter under the control of a controller, such as controller 125 (not shown in Figure 2), using pulse width modulation to provide positive DC voltage across output capacitor 270. In this example, transistor 245 operates as a positive boost transistor. Similarly, in one embodiment, inductor 240 operates in conjunction with transistor 250 and output diode 265 as a negative boost converter under the control of a controller, such as controller 125, using pulse width modulation to provide a negative DC voltage across output capacitor 275. In this example, transistor 250 operates as a negative boost transistor. [0019] In one embodiment, input circuit 110 may also include transistor 280 that is part of a step-down converter in a battery operating mode. For example, in a battery operating mode, controller 125 can direct relays 225 and 230 to switch from positions illustrated in Figure 2 to battery coupling positions 120 with inductors 235 and 240. Continuing with this example, the positive boost circuit including inductor 235, transistor 245 and output diode 260 can generate positive DC voltage across output capacitor 270 as discussed above in connection with the in-line mode of operation. In one embodiment, to generate negative voltage across output capacitor 275 in a battery operating mode, transistors 245 and 250 function as a step-down circuit with transistor 280 being turned on and off. For example, during each cycle, transistor 250 may turn on a period (for example 0.5 microsecond) before transistor 280, and transistor 280 may remain on for a period, for example 0.5 microsecond, after transistor 250 turn off, thus reducing the switching losses of transistor 280. [0020] As illustrated in Figure 2, transistor 280 is coupled between diode 255 and boost transistor 250. In this illustrated embodiment, transistor 280 may include an insulated gate bipolar transistor (IGBT) or a configured low power MOSFET device as battery voltage and negative output voltage at output capacitor 275, since, in this example, the voltage across transistor 280 during normal operation of input circuit 110 in a battery operating mode does not exceed a value substantially equal to battery voltage. It should be appreciated that other configurations are possible. For example, transistor 280 can be coupled between inductor 240 and output diode 265. [0021] In various embodiments, the configuration of the input circuit 110 differs from the embodiment of Figure 2. For example, as illustrated in Figure 2, the input circuit 110 includes input diodes 205 and 210 and input capacitors 215 and 220. In one embodiment, input capacitors 215 and 220 need not be used. In some embodiments, such as for an input DC voltage, input diodes 205 and 210 need not be used. Furthermore, in various embodiments, relays 225 and 230 can include transistors and diodes, and UPS 100 can derive power from both line and battery sources at substantially the same time. In some embodiments, the power supplies can be single-phase or multi-phase sources of various voltages. [0022] In some embodiments, and as described below, a controller such as controller 125 controls the operation of input circuit 110 to provide power factor correction at the input of the UPS 100 so that the input current is the input voltage of the UPS 100 is substantially in phase. Controller 125 may also control the mode of operation of input circuit 110, for example, by selectively switching between continuous and discontinuous modes of operation, to control the frequency of operation of input circuit 110. [0023] Figure 3 is a functional block diagram representing the uninterruptible power supply (UPS) 100 according to the invention. In one embodiment, UPS 100 includes at least one controller 125. For example, controller 125 can include at least one processor or other logic device. In some embodiments, controller 125 includes a digital signal processor (DSP) 303 and a field-programmable gate array (FPGA) 305. Controller 125 may also include at least one application-specific integrated circuit (ASIC) or other hardware , software, firmware or combinations thereof. In various embodiments, one or more controllers 125 may be part of the UPS 100 or external, but operatively coupled to the UPS 100. [0024] In one embodiment, controller 125 includes at least one control signal generator 307. Control signal generator 307 may be part of controller 125 or a separate device that outputs a control signal in response, at least in response. part, the instructions of controller 125. In one embodiment, control signal generator 307 includes a DSP 303 and FPGA 205. Control signal generator 307 may generate, form, or otherwise output a control signal, such as a pulse width modulation (PWM) control signal. In one embodiment, the control signal generator 307, for example, in combination with the controller 125, can adjust the duty cycle of a PWM control signal to switch the operating modes of the input circuit 110 between any of the continuous, discontinuous and quasi-discontinuous modes of operation. [0025] As illustrated in Figure 3, current sensor 310 can sample or otherwise determine inductor current in inductor 235, and current sensor 315 can sample or otherwise determine inductor current in inductor 240. In one embodiment, inductor current values identified by current sensors 310 and 315 are provided to controller 125. Based, at least in part, on one or more detected inductor current values, controller 125 can toggle the mode. of operating one or both transistors 245 and 250. In one embodiment, in response to current sensor 310 indicating that the current through inductor 235 is zero, gate unit 325 may turn on first switch 320, which includes transistor 245 For example, transistor 245 may turn on when the inductor current in inductor 235 is determined to be zero and when transistor 245 is off for a period that is greater than a predetermined period, which has the effect of cutting the input circuit with maximum operating frequency 110. [0026] Similarly, in one embodiment, in response to current sensor 315 indicating that the current through inductor 240 is zero, gate unit 335 may turn on second switch 330, which includes transistor 250. For example, transistor 250 can turn on when the inductor current in inductor 240 is determined to be zero and when transistor 250 is off for a period that is longer than a predetermined period, which also cuts the input circuit with maximum operating frequency 110. In various embodiments, gate units 325 and 335 can turn on and off respective transistors 245 and 250 independently of each other. [0027] Figure 3A is a functional block diagram representing the uninterruptible power supply (UPS) 100 according to the invention. Figure 3A illustrates a single-phase rectifier embodiment with AC input voltage 340 configured for a battery backup mode of operation with dual battery bus lines to positive battery terminal 345 and negative battery terminal 350. As illustrated in Figure 3A a switch, such as semiconductor controlled rectifier 355, can electrically connect positive battery terminal 345 with inductor 235, and a switch, such as semiconductor controlled rectifier 360, can electrically connect negative battery terminal 350 with inductor 240. As illustrated in Figure 3A, the control signal generator 307 of controller 125 may generate a pulse width modulation control signal to control the switching of the first switch 320 and the second switch 330 as described in relation to Figure 3. [0028] Figure 4 is a schematic diagram representing a three-phase rectifier 400 according to an embodiment of the invention. In one embodiment, the three-phase rectifier 400 is used with, or is part of, an uninterruptible power supply, such as the UPS 100. In one embodiment, the three-phase rectifier 400 is an input circuit that includes Phase voltage input lines A, Phase B and Phase C, respectively coupled with first inductor 405, second inductor 410 and third inductor 415. Each phase line may include at least one rectifying diode 420 for positive voltage boost converter operation and at least one diode rectification unit 425 for negative voltage boost converter operation. Three-phase rectifier 400 may also include output diodes 430 and 435 and output capacitors 440 and 445. Referring to Figure 4, it should be appreciated that the first switch 320, the output diode 430, and any of the first inductors 405, second inductor 410 and third inductor 415 may be part of a positive boost converter and that second switch 330, output diode 435 and any one of first inductor 405, second inductor 410, and third inductor 415 may be part of a step-down negative converter. [0029] With reference to Figure 4, when configured for three-phase operation with a grounded neutral, the rectifier 400, in one embodiment, operates in a quasi-discontinuous mode of operation. For example, the ON time of the first switch 320 and the second switch 330 may be a fixed period for a given load and input line voltage. In this example, the controller 125, through pulse width modulation, can control the OFF time of the first switch 320 and the second switch 330 based, for example, on the full reset current, i.e., the detected inductor current. by at least one of current sensor 310 and current sensor 315. In one embodiment, first switch 320 and second switch 330 remain off until the reset current is zero. The OFF time can change during the line cycle, thus changing the switching frequency with which the first switch 320 and second switch 330 are turned on and off throughout the entire line cycle. For example, the ON TON time of the first switch 320 and the second switch 330 may be the same or substantially the same when the operating frequency is the same or substantially the same at a point in time. Continuing with this example, the inductor currents detected by current sensor 310 and current sensor 315 can drop to zero at different times. In this example, the first switch 320 and the second switch 330 may turn off at different times (e.g., when an inductor current reaches zero) when the operating frequency may be the same or substantially the same at a point in time. [0030] In one embodiment, using the quasi-discontinuous mode discussed above, the elements of rectifier 400 (for example, those that function as a positive or negative boost converter) can operate at a low frequency when the input line voltage in Phase A, Phase B and Phase C is above a certain amount, such as 240V AC. For example, positive or negative pulse converters that are part of an input circuit (eg rectifier 400) may operate at frequencies lower than 20 kHz during heavy load or high input voltage conditions, thus becoming audible, since, in this example, the peak voltage of the input line can approach the output voltage of the boost converters. Also, under light load conditions, the input circuit operating frequency may increase to a high level which may be inefficient or unsustainable. [0031] In one embodiment, to control the operating frequency of the rectifier, the rectifier 400 includes at least one positive boost converter (for example, including the first switch 320, the output diode 430 and at least one of the first inductor 405 , second inductor 410 and third inductor 415) and at least one negative boost converter (e.g. including second switch 330, output diode 435 and at least one of first inductor 405, second inductor 410 and third 415) inductor which can operate in fixed frequency mode from 60 degrees to 120 degrees of the AC waveform, which limits the peak operating current. In this example, controller 125 can direct rectifier 400 to operate in continuous and near-discontinuous modes of operation by controlling first switch 320 and second switch 330, thus controlling the minimum and maximum operating frequency of rectifier 400. [0032] In one embodiment, the rectifier 400 operates in a battery mode. For example, rectifier 400 can include a dual battery bus with a positive battery terminal 450 and a negative battery terminal 455. Continuing with this example, in a battery operating mode, a switch can electrically connect the battery terminal positive 450 with any one of the first inductor 405 (as illustrated in Figure 4), the second inductor 410, and the third inductor 415. A switch may also electrically connect the negative battery terminal 455 with any one of the first inductor 405, the second inductor 410 (as illustrated in Figure 4) and third inductor 415. [0033] Referring to Figures 1 to 4, in one embodiment, the uninterruptible power supply 100 includes rectifier 400, transistor 245, transistor 250, first inductor 405, second inductor 410, and third inductor 415. In operation, rectifier 400 can be operatively coupled to controller 125, which can include DSP 303 and FPGA 305. Continuing with this embodiment, at least one of current sensors 310 and 315 can detect inductor current from at least one of the inductors. 405, 410, and 415 and can indicate the detected current value of the inductor to, for example, the DSP 303. In this example, the DSP 303 can generate a current error value based, in part, on the detected current value of the inductor. The current error value can be provided to the FPGA 305. The FPGA 205 can generate a pulse width modulation control signal based in part on the current error value, and the controller 125 can apply the signal from pulse-width modulation control at least one of transistors 245 and 250 to reversibly and selectively toggle their operating states between on and off states. By doing this, controller 125 can control the on and off time of transistors 245 and 250, and their operating state. For example, controller 125 can apply the pulse width modulation control signal to operate at least one of transistors 245 and 250 in two modes of operation, e.g., continuous and near-batch, during a line cycle. [0034] Figure 4A is a schematic diagram representing an OR configuration of a three-phase diode rectifier 400 according to an embodiment. As illustrated in Figure 4A, the three phases A, B, and C are connected in an OR diode configuration with the boost converter of inductor 460 (for example, inductor 460 and first switch 320) and with the boost converter of inductor 465 (by example, inductor 465 and second switch 330). As illustrated in Figure 4A, controller 125 controls the operation of the first switch 320 and the second switch 330 to shape the output current from 60 degrees to 120 degrees of the AC waveform when phases A, B and C are independent. In one embodiment, the circuit configuration for rectifier 400 illustrated in Figure 4A operates with average total harmonic distortion levels of about 30% or less. Referring to Figure 4A, during battery mode operation, a switch such as semiconductor controlled rectifier 470 can electrically connect positive battery terminal 450 with inductor 460, and a switch such as semiconductor controlled rectifier 475 semiconductor, can electrically connect negative battery terminal 455 with inductor 465. [0035] Figure 4B is a schematic diagram depicting a three-phase partially decoupled rectifier 400 with a single battery mode configuration according to an embodiment. Referring to Figure 4B, in a battery operating mode, a switch, such as a semiconductor-controlled rectifier, silicon-controlled rectifier, or other switch, can electronically connect the positive battery terminal 450 with the first inductor 405 as illustrated, or with second inductor 410 or third inductor 415 in other configurations. A switch may also electrically connect the negative battery terminal 455 with the second inductor 410, as illustrated, or with the first inductor 405 or third inductor 415 in other configurations. In a battery operating mode, battery pack 480, which includes one or more batteries, can supply power to rectifier 400. [0036] With continued reference to Figures 1 and 4B, in an embodiment where the rectifier 400 operates in a battery mode, the switching pattern of the first switch 320 and the second switch 330 is synchronized with the load (e.g., load 105 of Figure 1, ie an inverter load). For example, when the inverter 105 produces the positive half of a sine wave, the switch operating as the negative boost switch (eg, second switch 330) can be held in an on position with the switch operating as the positive boost switch ( for example, first switch 320) which is pulse width modulated by controller 125. During the negative half of the sine wave output of inverter 105, the switch operating as positive boost switch (for example, first switch 320) may be held in an on position with the switch operating as the negative boost switch (eg, second switch 330) being pulse width modulated by controller 125. In one embodiment, the configuration of rectifier 400 of Figure 4B operates with a single set of battery 480. In another embodiment, this rectifier configuration operates with multiple power modules that share battery packs. [0037] Figure 4C is a schematic diagram representing a three-phase partially decoupled rectifier 400 that operates from a single battery bus in a battery mode configuration using the step-down switch 485 according to one embodiment. As illustrated in Figure 4C, the 485 step-down switch connects the battery voltage from battery pack 480 to diode 435. In one embodiment, the step-down-lift switch 485 includes a switch with a nominal voltage of at least 900 volts. As illustrated in Figure 4C, diode 435 operates as a negative boost diode and, in one embodiment, having the configuration illustrated in Figure 4C, diode 435 has a nominal voltage of at least 900 volts. The configuration of rectifier 400, as illustrated in Figure 4C, in one embodiment, has an operating frequency of 30 kHz or less. In various embodiments, step-down switch 485 and diode 435 may have other voltage ratings, both greater and less than 900 volts, such as 800 volts or 1000 volts, and the operating frequency of rectifier 400 may be greater than 30 kHz in some embodiments. [0038] In a battery operating mode, the battery pack 480 is coupled with the step-down switch 485, which is, in turn, coupled to the ground conductor 487, which also receives the battery bus line (BBL) 491 and the battery bus line return to neutral (BBLRTN) 493, and to diode 489. In one embodiment, rectifier 400, having the configuration illustrated in Figure 4C, includes diode 495 engaging the first switch 320 and the second switch 330. [0039] Figure 4D is a schematic diagram representing a three-phase partially decoupled rectifier 400 that operates from a single battery bus in a battery mode configuration using the step-down switch 485 according to one embodiment. As illustrated in Figure 4D, the step-down switch 485 connects the battery voltage from battery pack 480 to the second switch 330 (eg, operating as a negative boost switch). Referring to Figure 4D, in one embodiment, the 485 step-down switch includes a power field effect transistor (FET) having a low resistance to reduce conduction or switching losses in the 485 step-down switch. Figure 4D, second switch 330 operates as a negative boost switch, and diode 435 operates as a negative boost diode with a nominal voltage, in one embodiment, of at least 1200 volts. In one embodiment, rectifier 400, having the configuration illustrated in Figure 4D, has a switching frequency of 80 kHz or less. In various embodiments, the nominal voltage of the diode 435 and the maximum switching frequency can vary. For example, diode 435 may have a nominal voltage of less than 1200 volts (eg 1100 volts) and rectifier 400, as illustrated in Figure 4D, may have a switching frequency greater than 80 kHz, (eg 90 kHz ). [0040] In a battery operating mode, the battery pack 480 is coupled with the step-down switch 485, which, in turn, is coupled to the ground conductor 487, which also receives the battery bus line ( BBL) 491 and the battery bus line return to neutral (BBLRTN) 493, and to diode 489. In one embodiment, rectifier 400, having the configuration illustrated in Figure 4D, includes diode 495 coupling the first switch 320 and the second switch 330. As illustrated in Figures 4A through 4D, the controller 125 may generate a pulse width modulation control signal to control the switching of the first switch 320 and the second switch 330 as described in relation to Figure 4. [0041] In some embodiments, and with reference to Figures 4 - 4D and 5, at any point in time, there may be two positive phases and one negative phase, or two negative phases and one positive phase. For example, Figure 5 represents a +/- 400v three-phase line cycle according to an embodiment of the invention. As illustrated in Figure 5, Phase A and Phase B can be positive to neutral and Phase C can be negative to neutral. In this example, the current increases in the first inductor 405 and in the second inductor 410 when the first switch 320 is turned on, and the peak current in the first inductor 405 and in the second inductor 410 depends on the phase voltage in the respective inductor. Continuing with this example, when the first switch 320 turns off, the voltage across the first inductor 405 and the second inductor 410 may be different, but the current from each of these inductors flows through the respective rectifier diode 420 and output diode 430 to the load (not shown in Figure 4) and output capacitor 440. In this example, current sensor 310 measures the total current of first inductor 405 and second inductor 410 when first switch 320 is turned off. Controller 125 may maintain first switch 320 in an off configuration until the total current of first inductor 405 and second inductor 410, measured by current sensor 310, reaches zero or is determined to be substantially zero. In other words, in this example of near continuous operation, controller 125 activates first switch 320 when the inductor current associated with that switch reaches zero. In addition to the total current reaching zero, the first switch 320 may be turned off for a minimum period before the controller 125 instructs the first switch 320 to revert to an open setting. [0042] The rectifier 400 can operate with two phases negative and one positive, in relation to the neutral. For example, at various points in the line cycle, Phase A can be positive and Phase B and Phase C can be negative relative to neutral. In this example, the total inductor current may increase in the second inductor 410 and in the third inductor 415 when the second switch 330 is turned on. When the second switch 330 turns off, the current sensor 315 measures the total inductor current from the second inductor 410 and the third inductor 415. When that total inductor current reaches zero, the controller 125 turns on the second switch 330. current sensor 315 detects zero current, second switch 330 may remain off for a minimum period before turning back on. It should be appreciated that these examples are illustrative and that the peak current measured by the first current sensor 310 and the second current sensor 315 may vary depending on how many phases are adding current to the rectifier 400. [0043] Figure 6 is a schematic diagram representing an embodiment of controller 125. In one embodiment, controller 125 includes at least one zero current detector 605. For example, at least one of current sensors 310 and 315 may indicate the value of the inductor current detected in the rectifier 400. The zero current detector 605 can apply the TON signal (e.g., a pulse width modulating signal) to, for example, at least one of the first switch 320 and the second switch 330 for changing the operating state of at least one of transistors 245 and 250. In one embodiment, zero current detector 605 operates with TON signal generator 610 to generate the TON signal. For example, the analog-to-digital converter 615 can provide a signal to the difference equation 620, the output of which can indicate that at least one of transistors 245 and 250 must be turned on, thus increasing the inductor current. In some embodiments, the TON signal generator 610 may indicate the ON time of one of the transistors 245, 250 causing the inductor current to decrease. In one embodiment, the TON610 signal generator may also include the enable signal 625. [0044] Thus, in various embodiments, controller 125 toggles the operating state of transistors 245 and 250 when the total current is determined to be zero. An example of quasi-batch operation of rectifier 400 is illustrated in Figure 7, which represents the inductor current in rectifier 400 operating in quasi-batch mode during a line cycle. As illustrated in Figure 7, the peak current varies depending on how many phases are supplying current to the output, and the current varies between substantially zero and 40A. Figure 8 illustrates the example of Figure 7, enlarged in a time of approximately 25 ms, where it can be seen that, in an embodiment of a quasi-discontinuous mode of operation, the inductor current of the rectifier 400 may drop to zero before increasing again, without remaining at zero for any substantial period. The results in Figures 7 and 8 are illustrative. In one embodiment, rectifier 400 can produce the current illustrated in Figures 7 and 8 when Phase A, Phase B and Phase C operate at 160V AC and rectifier 400 has an output power of 5890W with first inductor 405, the second inductor 410 and the third inductor 415 each having an inductance of 100μH that does not oscillate with the load current. [0045] Referring to Figures 1, 3 and 4, controller 125 can control input circuit 110 or rectifier 400 to provide power factor correction in quasi-batch mode using analog and digital circuits, including digital signal processors 303 and field-programmable gate arrays 305. For example, an analog portion of controller 125 can detect a zero current state associated with at least one inductor. In one embodiment, this indicates that a new switching cycle can begin and controller 125 can continue to send a signal to turn on a switch (e.g., first switch 320 or second switch 330) for a period TON, which can be determined by the output of a difference equation. In one embodiment, controller 125 also includes an enable signal which, for example, must be in a particular state (e.g., a logic one or high state) to allow controller 125 to operate the switches of input rectifier 400. [0046] In one embodiment, the time TON for input circuit switches (eg transistors 245 or 250) may be different for different line cycles to regulate the output voltage. For example, a difference equation can define the time TON for a line cycle of rectifier 400 and controller 125 can include a timer to determine whether the time TON of rectifier 400 (or converter portions thereof) occurs for at least one period. minimum, for example, before a switch can be turned off. For example, to maintain a period during which the inductor current is greater than zero at 12.5μs (corresponding to a switching frequency of approximately 80 kHz), the TON time can be 6.25μs in an example having an increase linear inductor current during transistor on time and linear inductor current drop during transistor off time. [0047] Controller 125 may also limit the maximum operating frequency of input circuits, such as rectifier 400. In one embodiment, at light loads, if otherwise uncontrolled, the switching frequency of the input circuit may increase to a level that exceeds the ability of switches to regulate circuit operation. In this example, controller 125 can limit the maximum switching frequency of rectifier 400. Although the maximum operating frequency of rectifier 400 may vary, in one embodiment, controller 125 limits the maximum switching frequency of rectifier 400 to 130 kHz and, in another embodiment, controller 125 limits the maximum switching frequency of rectifier 400 to 80 kHz. [0048] Figure 9 represents a graph that illustrates the rectifier 400 operating in an almost discontinuous mode of operation. As illustrated in Figure 9, the TON period starts when the inductor current is zero. It should be noted that the inductor current can be measured by current sensors 310 or 315 at various points of the rectifier 400, with the exception of the first inductor 405, the second inductor 410 and the third inductor 415, and that this current can also be referred to as a switch current, rectifier current, or total inductor current, for example. As illustrated in Figure 9, the inductor current increases during the TON and peaks for a given TP period at the end of the TON time, at which point the inductor current begins to decrease to zero. The TP period may vary. In one embodiment, TP is approximately 12.5µs. In one embodiment, when a maximum inductor current is reached, the TON period may end, allowing the inductor current to decrease to zero. In this illustrative embodiment of quasi-discontinuous operation, the TON period begins when the inductor current reaches zero, and in one embodiment, the inductor current does not stay at zero for more than a fraction of a millisecond. Although not illustrated in Figure 9, it is appreciated that, in one embodiment, in a continuous mode of operation, the inductor current never reaches zero during a TP period. [0049] Figure 10 illustrates a graph representing an embodiment in which the switching frequency of the rectifier 400 is limited to 80 kHz over a complete line cycle. In the example illustrated in Figure 10, rectifier 400 has 500W of load power and provides 1000W of output power. As indicated by the solid line in Figure 10, controller 125 can limit the switching frequency of rectifier 400 to 80 kHz during one full line cycle. In the absence of controller 125, at light loads, the switching frequency in one embodiment would appear as indicated by the dashed lines in Figure 10, ranging between approximately 100 kHz and 160 kHz, which may exceed the switching capacity of rectifier 400. [0050] Figure 11 illustrates a graph representing an embodiment in which the switching frequency of rectifier 400 is limited to 80 kHz in a portion of a line cycle. In one embodiment, rectifier 400 can operate at the switching frequency as illustrated by the solid line when rectifier 400 has 500W of load power and provides 2000W of output power. In this illustrative embodiment, the dashed lines indicate the switching frequency of the rectifier 400 in the absence of instructions from the controller 125, limit the maximum switching frequency, for example by controlling the time TON during which a switch, such as the first switch 320, will remain on. By controlling the maximum operating frequency of rectifier 400 so that it does not exceed a threshold value during a line cycle, operation of rectifier 400 remains within the functional ranges of first switch 320 and second switch 330. [0051] Figure 12 illustrates a graph representing an embodiment where the switching frequency of the rectifier 400 is not limited during a line cycle, because, for example, the switching frequency of the rectifier 400 remains below 80 kHz throughout the line cycle. When rectifier 400 has 500W of load power and provides 2000W of output power, as illustrated in Figure 12, the switching frequency of rectifier 400 may remain below a threshold value, such as 80 kHz, for example, when the first inductor 405, second inductor 410, and third inductor 415 include oscillating inductors that have greater inductance at a lower current. Higher inductance values of oscillating inductors at low currents can keep the maximum operating frequency below a threshold value, such as 80 kHz, as illustrated in Figure 12, or other frequencies, such as 130 kHz or 160 kHz. In one embodiment, controller 125 includes at least one FPGA 305 and at least one DSP 303 to control the maximum switching frequency of switches 320 and 330 and the near-discontinuous operating switching point for continuous operation. The DSP 303 can generate voltage error gain to reduce circuit complexity and part count, and to achieve low average total harmonic distortion. [0052] In addition to controlling the maximum operating, or switching, frequency of rectifier 400, in one embodiment, controller 125 can control the minimum frequency of rectifier 400 to keep it above a minimum threshold value. For example, controller 125 can limit the minimum frequency of rectifier 400 to a level above the human hearing range or about 20 kHz. For example, at high line voltages in quasi-discontinuous operating mode, the operating frequency of rectifier 400 may become low enough to be audible. In one embodiment, controller 125 limits the minimum operating frequency of rectifier 400 (or its positive/negative converter components) by transitioning from a quasi-batch mode of operation to a continuous, fixed-frequency mode of operation. During continuous operating mode, for example, the inductor current picked up by current sensor 310 or current sensor 315 does not reach zero. In an embodiment having a three-phase rectifier, such as rectifier 400, this transition occurs during a portion of the line cycle where the phase voltages of the three phases are mutually exclusive. For example, this transition occurs between 60 and 120 degrees and between 240 and 300 degrees of a 360 degree line cycle. [0053] For example, controller 125 can position switches 320 and 330 to operate in a quasi-discontinuous mode during a 0 to 60 degree phase angle portion of the line cycle. To limit the minimum operating frequency of rectifier 400, in one embodiment, controller 125 may instruct switches 320 and 330 to transition to a continuous fixed frequency operating mode during phase angles of 60-120 degrees. Continuing with this illustrative embodiment, controller 125 can transition from switches 320 and 330 back to near-batch mode from 120-240 degrees, and, from 240 to 300 degrees, transition to an operating mode can again occur. continuous. Finally, in this example, controller 125 can instruct switches 320 and 330 to operate in near-batch mode from phase angles of 300 to 360 degrees of the line cycle. In one embodiment, input circuits, such as rectifier 400 with three-phase input voltage main lines, operate in conjunction with controller 125 to toggle between continuous, near-discontinuous rectifier modes of operation. This limits the highest and lowest operating frequency of the rectifier 400 to, for example, between 20 kHz and 80 kHz, preventing high frequency operation beyond switching capability at light loads and preventing audible frequency operation at heavy loads. In this illustrative embodiment, the rectifier 400, or its converters, can operate in the near discontinuous mode of 0 - 60, 120 - 240 and 300 - 360 degrees and in the continuous mode of 60 - 120 and 240 - 300 degrees. Such operation can keep the operating frequency of rectifier 400 above a threshold value, such as 20 kHz. [0054] In one embodiment, to transition between quasi-discontinuous and continuous modes of operation uninterruptedly, controller 125 includes at least one digital signal processor (DSP) 303 and at least one field-programmable gate array ( FPGA) 305. In this illustrative embodiment, a current circuit in the DSP 303 may operate in parallel with the total inductor current during the variable frequency quasi-discontinuous mode of operation. This parallel current loop configuration also reduces mean total harmonic distortion by maintaining an uninterrupted inductor current value. In one embodiment, when the phase voltages are independent of each other, for example, between 60 and 120 degrees, the DSP 303 of the controller 125 can command the FPGA 305 of the controller 125 to operate the rectifier 400 in a continuous mode of operation of fixed frequency. For example, the DSP 303 of controller 125 may include a reference current generator. By evaluating the measured current (for example, in at least one of the current sensor 310 and the current sensor 315) and the reference current generated by the reference current generator, the DSP 303 of the controller 125 can generate a value. of current error which, in this embodiment, is the difference between the generated reference current and the actual measured current. The DSP 303 may also include a voltage difference equation to generate a voltage error value. Continuing with this illustrative embodiment, information generated by the DSP 303, such as current or voltage error values, can be provided to the FPGA 305. In one embodiment, the FPGA 305 processes at least one of the current and voltage error values. in a difference equation, and the output of this calculation includes a modulated pulse width modulation control signal to provide power factor correction of the rectifier 400. For example, the controller 125 can adjust a duty cycle of a signal of pulse width modulation control to drive the power factor of the rectifier 400 (or any other converter) to the unit. In one embodiment, the FPGA 305 includes at least one multiplexer. [0055] Controller 125 can adjust the duty cycle of the pulse width modulation control signal for selective transition of input circuit transistors, such as those of the first switch 320 and the second switch 330, between continuous modes of operation fixed frequency and variable frequency quasi-discontinuous to operate rectifier 400 within a frequency range. In one embodiment, this frequency range is between 20 kHz and 80 kHz. In some embodiments, this frequency range includes a minimum frequency that is above the human hearing range. In some embodiments, the frequency range is between 20 kHz and 130 kHz. [0056] In one embodiment, controller 125 may adjust at least one duty cycle of at least one pulse width modulation control signal to independently provide power factor correction to both positive and negative converter circuits of rectifier 400 and regulate the output voltage across capacitors 440 and 445. For example, controller 125 can adjust a first cycle of operating the pulse width modulation signal to provide power factor correction to a positive converter of rectifier 400 and can adjust independently a second pulse width modulation signal operating cycle to provide power factor correction to a negative converter of rectifier 400. In one embodiment, the positive and negative converters can operate simultaneously in different modes. For example, pulse width modulation of one or more control signals can provide positive power factor correction to a positive converter operating in quasi-batch mode, and negative power factor correction to a negative converter operating in the continuous mode. It should be appreciated that the positive converter can also operate in continuous mode while the negative converter operates in quasi-discontinuous mode. [0057] In one embodiment, the uninterruptible power supply 100 controlled in accordance with embodiments of the present invention exhibits low total harmonic distortion. In some embodiments, a low-pass LC filter, or other filters with various combinations of resistors, inductors, and capacitors, can filter out average total harmonic distortion including switching frequency voltage harmonics generated by the first switch 320 and the second switch 330. In addition, as noted above, the DSP 303-based control of the rectifier 400 in quasi-batch operating mode where the controller 125 includes a DSP 303 with a parallel current loop configuration can also reduce the distortion of the average total harmonic current. . The amount of total harmonic distortion at the output of the UPS 100 can vary. In one embodiment, total harmonic distortion is less than or equal to 3.4% of a UPS output signal. In one embodiment, the rectifier 400 meets the IEC 61000-3-12 standard for harmonic current. [0058] Figure 13 is a flowchart representing a 1300 method of operating a system such as an uninterruptible power supply according to an embodiment. In one embodiment, method 1300 includes a method for operating an uninterruptible power supply that has at least one input circuit, a plurality of transistors, and at least one controller. The controller may include at least one digital signal processor and at least one field-programmable gate array. [0059] In one embodiment, method 1300 includes an input circuit inductor current sensing action (ACTION 1305). For example, sensing inductor current (ACTION 1305) can include sensing or gauging inductor current at various points in the input circuit. For example, inductor current sensing (ACTION 1305) may include sensing current in single-phase or three-phase rectifier inductors, or at other points in the input circuit, such as a portion of a three-phase rectifier circuit located between rectifier diodes and sensing inductor current (ACTION 1305) may include sensing current from more than one inductor. For example, an input circuit may include two boost converter circuits, which may be referred to as positive and negative boost converters (eg step-down). In this example, a current sensor can detect inductor current (ACTION 1305) from the input circuit boost converter circuits. [0060] In one embodiment, method 1300 includes an action of providing a sensed current value from the inductor to a controller (ACTION 1310). Providing the sensed current value of the inductor (ACTION 1310) in one embodiment includes providing the sensed current value of the inductor to a digital signal processor. This current value may be supplied (ACTION 1310) to a digital signal processor, digital logic device, controller, processor, logic circuit, or other device configured for electronic communication with a current sensor or other device that detects circuit current values. input including inductor current. [0061] Method 1300 includes an action of generating a current error value (ACTION 1315). In one embodiment, generating the current error value (ACTION 1315) includes generating the current error value based at least in part on the sensed current value of the inductor. For example, generating the current error value (ACTION 315) may include determining the difference between the detected or measured current value of the inductor (ACTION 1305) and a current reference value that was generated, for example, by the digital signal processor associated with the controller. [0062] In one embodiment, method 1300 includes an action of providing the current error value to the controller (ACTION 1320). Providing the current error value (ACTION 1320) in one embodiment includes providing the current error value to a field-programmable gate array. The current error value may be provided (ACTION 1320) to a field-programmable array of gates, digital logic device, controller, processor, logic circuit, or other device configured for electronic communication with, for example, a digital signal processor or another device that generates current error values (ACTION 1315). [0063] Method 1300, in one embodiment, also includes an action of generating a pulse width modulation (PWM) control signal (ACTION 1325). For example, a PWM control signal can be generated (ACTION 1325) based in part on the current error value. In one embodiment, generating a PWM control signal (ACTION 1325) includes generating a plurality of PWM control signals, such as first and second pulse width modulation control signals. [0064] In one embodiment, generating a pulse width modulation control signal (ACTION 1325) includes generating a plurality of PWM control signals independently of each other. For example, generating a pulse width modulation control signal (ACTION 1325) may include generating a first PWM control signal to a first input circuit boost converter and generating a second control signal. from PWM to a second input circuit boost converter. In this example, the first and second PWM control signals can be generated independently based, for example, on different inductor currents, different current error values or other different characteristics among a plurality of boost converters (including step-down converters -elevator) that are part of at least one input circuit. [0065] Method 1300 includes actions of generating a voltage error value (ACTION 1330), such as the difference between an actual and a desired output voltage, and providing that voltage error value (ACTION 1335) to the controller or an associated component, such as a field-programmable array of gates. For example, generating the voltage error value (ACTION 1330) may include the use of a digital signal processor, and the voltage error value may be provided (ACTION 1335) to a field programmable gate array device digital logic controller, processor, logic circuit, or other device configured for electronic communication with, for example, a digital signal processor or other device that generates a voltage error value (ACTION 1330). [0066] In one embodiment, method 1300 includes an action of applying the pulse width modulation control signal (ACTION 1340). For example, applying the PWM control signal (ACTION 1340) may include applying the PWM control signal to at least one transistor that is part of the input circuit to control a switching frequency. The transistor to which the PWM control signal can be applied (ACTION 1340) can be a transistor that is part of a boost converter of the input circuit and the transistor can be part of a switch driven by a gate unit that is in communication with the controller or other device, such as a field-programmable port array. [0067] In one embodiment, applying the PWM control signal (ACTION 1340) includes applying the PWM modulation control signal to one of a first transistor and a second transistor in the input circuit to control its switching frequency. In various embodiments, the frequency can be controlled to remain inaudible to humans (e.g., above 20kHz) below an upper limit (e.g., below 130kHz or below 80kHz) or within a certain range. [0068] In some embodiments, different PWM control signals can be applied to different transistors. For example, applying the PWM control signal (ACTION 1340) may include applying a first PWM control signal to a first transistor that may be part of a first boost converter circuit, and applying a second signal from PWM control to a second transistor that can be part of a second boost converter circuit. (Boost converter circuits and their portions may also be referred to simply as boost converters). In one embodiment, method 1300 includes an action of switching a boost converter mode of operation (ACTION 1345). For example, applying the PWM control signal (ACTION 1340) includes applying the PWM control signal to a transistor to toggle the operating mode of the boost converter circuit (ACTION 1345) associated with that transistor. For example, boost converters can operate in a continuous mode, where the inductor current in the boost converter remains above zero during a line cycle. Boost converters can also operate in a discontinuous mode where the inductor current drops and remains at zero for more than a minimum period. Additionally, boost converters can operate in a quasi-discontinuous mode, in which the inductor current in the boost converter decreases and reaches zero, but does not remain at zero for an operationally significant period. For example, in near-discontinuous operation, the PWM control signal can instruct the transistor to enter an ON state when the inductor current is determined to be zero. In this example, this causes the inductor current to increase, as illustrated in Figures 7-9. [0069] Continuing, in one embodiment, the application of the PWM control signal (ACTION 1340) includes applying at least one PWM control signal to at least one transistor to reversibly switch an operating mode of a boost converter ( ACTION 1345), which includes the transistor, between continuous and quasi-discontinuous operating modes. In this embodiment, the inductor current does not remain at zero for an operationally significant period during a line cycle. [0070] Boost converters can alternate operating modes during various parts of a line cycle. For example, an input circuit that includes a three-phase rectifier may operate during a 0 - 360 AC line cycle, referred to simply as a line cycle. In one embodiment, switching the boost converter operating mode (ACTION 1345) includes switching the operating mode of a boost converter from quasi-discontinuous variable frequency operation to continuous fixed frequency operation during a phase angle portion of 0 to 60 degrees of line cycle. In some embodiments, switching the boost converter operating mode (ACTION 1345) may also include controlling transistor switching to operate a boost converter in a quasi-discontinuous variable frequency operating mode during portions of the 060 phase angle, 120-240 and 300-360 degrees of line cycle. Switching the boost converter operating mode (ACTION 1345) may also include transistor switching control to operate a boost converter in a continuous fixed frequency operating mode (eg, 80 kHz, 90 kHz, or 130 kHz) during 60-120 and 240 - 300 - 360 degree phase angle portions of the line cycle. [0071] In one embodiment, method 1300 includes an action of switching a transistor (ACTION 1350) to an ON state when the detected current value is zero or substantially zero. Transistor state switching (ACTION 1350) may include adjusting the duty cycle of the PWM control signal to trigger transistor switching. For example, switching the transistor state (ACTION 1350) may include adjusting a PWM control signal applied to a transistor (ACTION 1340) to reversibly switch at least one transistor between the ON and OFF states. In one embodiment, when a zero inductor current is detected (ACTION 1305), a PWM signal is generated (ACTION 1325) and applied to a transistor (ACTION 1340) to instruct that transistor to enter an ON state (ACTION 1350) , causing the current to increase from zero. [0072] In one embodiment, the operating frequency, or switching, of an input circuit (or some of its components, such as transistors and boost converters) (ACTIONS 1345, 1350) can be variable during quasi-discontinuous and fixed operation during continuous operation. In some embodiments, application of the PWM control signal (ACTION 1340) to the transistor can reversibly switch input circuit operation between any of continuous, discontinuous, or quasi-discontinuous modes of operation. [0073] Note that, in Figures 1 to 13, the items listed are presented as individual elements. In actual implementations of the systems and methods described in this document, however, they may be inseparable components from other electronic devices, such as a digital computer. Thus, the actions described above can be implemented, at least in part, in software that can be incorporated into an article of manufacture that includes a program storage medium. The program storage medium includes data signals embedded in one or more of a carrier wave, a computer disk (magnetic or optical (eg, CD or DVD or both), non-volatile memory, tape, a system memory, and a computer hard drive. [0074] Considering the above, it will be appreciated that systems and methods for operating uninterruptible power supplies and other systems provide a simple and effective way to control the operating frequency of the input circuit. Systems and methods according to the various embodiments can transition transistor states and control the operation of the boost converter circuit. This provides an uninterruptible power supply or other system with robust power factor correction capability and reduced total harmonic distortion. [0075] All references to front and back, left and right, top and bottom, top and bottom are for the convenience of description, not to limit current systems and methods or their components to any positional or spatial orientation. [0076] Any reference to embodiments or elements or actions of the systems and methods referred to herein in the singular may also encompass embodiments that include a plurality of such elements, and any references in the plural to any embodiment or element or action herein may also encompass embodiments that include just a single element. References in singular or plural form are not intended to limit the systems or methods disclosed herein, their components, actions or elements. [0077] Any embodiment described herein may be combined with any other embodiment, and references to "an embodiment", "some embodiments", "an alternative embodiment", "several embodiments", "an embodiment" or the like are not necessarily mutually unique and are intended to indicate that a particular feature, structure or feature described in connection with the embodiment may be included in at least one embodiment. Such terms used herein do not necessarily all refer to the same embodiment. Any achievement may be combined with any other achievement in any way consistent with the objectives, purposes and needs disclosed herein. [0078] References to "or" may be considered all-inclusive, so any terms described using "or" may indicate any one of a single, more than one, and all of the terms described. [0079] When the technical characteristics of the drawings, detailed description or any claim are followed by reference signs, the reference signs have been included for the sole purpose of increasing the intelligibility of the drawings, detailed description and claims. Consequently, neither the reference signs nor their absence have any limiting effect on the scope of any claim elements. [0080] A person skilled in the art will understand that the systems and methods described in this document can be incorporated into other specific forms without departing from the spirit or its essential characteristics. For example, the systems and methods described in this document are not limited to use with uninterruptible power supplies and can be used with other power supplies and other systems in general. Furthermore, the input circuits described in this document are not limited to rectifier 400. Rectifiers and circuit configurations other than rectifier 400 and input circuit 110, and embodiments described in relation to rectifier 400 and input circuit 110 can be used with others power supplies and systems. The systems and methods described in this document include single-phase and three-phase rectifiers. For example, the single-phase power factor correction rectifier topology may have a maximum switching frequency of approximately 80 kHz, or half the sampling frequency. A three-phase partially decoupled power factor correction rectifier topology may have a maximum switching frequency of 130 kHz, which, in one embodiment, is the maximum frequency limited by rectifier switching devices. A three-phase fully decoupled power factor correction rectifier topology can have a maximum switching frequency of 40 kHz, or a quarter of the sampling frequency. The foregoing embodiments should therefore be considered in all respects illustrative rather than limiting the systems and methods described. The scope of the systems and methods described in this document is thus indicated by the appended claims, rather than the foregoing description, and all changes which fall within the meaning and equivalence range of the claims are therefore included therein.
权利要求:
Claims (15) [0001] 1. An uninterruptible power supply comprising: an input circuit (110), including a first transistor (245) and a first inductor (235), and configured to receive an AC voltage at an input (130, 135) and provide a voltage. CC at an output (150, 155); a controller (125) having a digital signal processor (303) and a field-programmable gate array (305) and coupled to the input circuitry for detecting inductor current and for providing a sensed inductor current value to the input processor. digital signal, the controller configured to apply a first pulse width modulation control signal to the first transistor to adjust a switching frequency of the first transistor to generate the DC voltage at the output; characterized in that a second transistor (250) is further provided, and wherein the first transistor forms part of a first boost converter circuit; wherein the second transistor forms part of a second first boost converter circuit; and that the input circuit includes a three-phase rectifier (400); wherein the controller is further configured to apply the first pulse-width modulation control signal to the first transistor to switch an operating mode of the first boost converter circuit between variable frequency batch and fixed frequency continuous operating modes; and wherein the controller is further configured to apply a second pulse width modulation control signal to the second transistor to toggle an operating mode of the second boost converter circuit between variable frequency batch and fixed frequency continuous operating modes. [0002] 2. Uninterruptible power supply according to claim 1, characterized in that: the digital signal processor is configured to generate a current error value, based in part on the value of the detected inductor current and to provide the current error value for the field-programmable gate array, and the field-programmable gate array is configured to generate the pulse width modulation control signal based in part on the current error value. [0003] 3. Uninterruptible power supply according to claim 1, characterized in that in one mode, the first boost converter circuit operates in the quasi-discontinuous variable frequency operation mode, and the second boost converter circuit simultaneously operates in the fixed frequency continuous operating mode. [0004] 4. Uninterruptible power supply according to claim 1, characterized in that at least one of the first transistor and second transistor switches to the state when the value of the detected inductor current drops substantially to zero. [0005] 5. Uninterruptible power supply according to claim 1, characterized in that: the three-phase rectifier is configured for operation during a line cycle with a first phase voltage, a second phase voltage, and a third phase voltage. phase; and the controller is further configured to alternate the operating mode of a first boost converter circuit and the second boost converter circuit during a part of the line cycle where each first phase voltage, second phase voltage, and third phase voltage are mutually exclusive. [0006] 6. Uninterruptible power supply according to claim 1, characterized in that the digital signal processor is further configured to generate a voltage error value based on a DC voltage value at the output and to provide the value of voltage error for the field-programmable gate array, and the field-programmable gate array is further configured to generate the pulse width modulation control signal based in part on the voltage error value. [0007] 7. Uninterruptible power supply according to claim 1, characterized in that: the switching frequency of the first transistor remains between 20 kHz and 130 kHz during a line cycle of the three-phase rectifier. [0008] 8. Uninterruptible power supply according to claim 1, characterized in that: the three-phase rectifier including the first inductor, a second inductor, and a third inductor; the detected inductor current includes current from at least two of the first inductor, the second inductor and the third inductor. [0009] 9. Uninterruptible power supply according to claim 1, characterized in that the first transistor is in one of the on or off state for at least a predetermined amount of time before switching to the other of the on or off state. [0010] 10. Uninterruptible power supply according to claim 1, characterized in that one of the first transistor and the second transistor reversibly alternate between a plurality of on state and off state, and in which a period of time between a first state on and a subsequent on state is approximately 12.5 µs. [0011] 11. Uninterruptible power supply according to claim 1, characterized in that the controller is further configured to apply the first pulse width modulation control signal to the first transistor to toggle an operating mode of the first converter circuit boost between discontinuous variable frequency only and continuous fixed frequency modes of operation during a first portion of a line cycle; and wherein the controller is further configured to apply a second pulse width modulation control signal to the second transistor to toggle an operating mode of the second boost converter circuit between variable frequency and continuous fixed frequency discontinuous operating modes during a second part of the line cycle. [0012] 12. Method of operating an uninterruptible power supply including an input circuit (110) and a controller (125), the input circuit having a first transistor (245), a first inductor (235), and a second transistor ( 250), wherein the first transistor forms part of a first boost converter circuit and the second transistor forms part of a second first boost converter circuit, and controller having a digital signal processor and a field-programmable gate array, the method comprising: detecting the inductor current of the input circuit; providing a sensed inductor current value to the digital signal processor; generate a current error value, based in part on the detected inductor current value; providing the current error value to the field programmable gate array, generating a pulse width modulation control signal based in part on the current error value; applying the first pulse width modulation control signal to the first transistor to control a switching frequency of one of the first transistor and the second transistor; characterized in that the method further provides: applying the first pulse-width modulation control signal to the first transistor to switch an operating mode of the first boost converter circuit between continuous variable-only continuous-frequency and fixed-frequency continuous operating modes ; and applying a second pulse width modulation control signal to the second transistor to toggle an operating mode of the second boost converter circuit between continuous variable frequency only continuous operating and fixed frequency operating modes. [0013] 13. Method according to claim 12, characterized in that it further comprises: generating an input circuit voltage error value; provide the voltage error value for the field programmable gate array; and generating the first pulse width modulation control signal based in part on the voltage error value. [0014] 14. Method according to claim 12, characterized in that the input circuit includes a three-phase rectifier having a plurality of inductors including the first inductor, and in which the inductor current detection of the input circuit further includes: detecting inductor current from at least two of the plurality of inductors. [0015] 15. The method of claim 12, characterized in that applying the first pulse width modulation control signal to the first transistor to switch an operating mode of the first boost converter circuit between the frequency operating modes continuous only variable and continuous fixed frequency comprises applying the first pulse width modulation control signal during a first portion of a line cycle; and applying a second pulse-width modulation control signal to the second transistor to switch an operation mode of the second boost converter circuit between continuous variable frequency only and continuous fixed frequency operating modes comprises applying the second modulation control signal of pulse width during a second part of the line cycle.
类似技术:
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同族专利:
公开号 | 公开日 CN102804547A|2012-11-28| EP2443723B1|2013-05-08| BR112012000193A2|2017-01-24| RU2011151481A|2013-07-27| AU2010260426A1|2012-01-19| ES2424090T3|2013-09-27| RU2538904C2|2015-01-10| EP2443723A2|2012-04-25| CA2765447A1|2010-12-23| CN102804547B|2014-12-10| US20100315849A1|2010-12-16| US8228046B2|2012-07-24| WO2010147731A3|2011-03-31| WO2010147731A2|2010-12-23| AU2010260426B2|2015-06-18|
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法律状态:
2017-03-14| B11A| Dismissal acc. art.33 of ipl - examination not requested within 36 months of filing| 2017-06-27| B04C| Request for examination: application reinstated [chapter 4.3 patent gazette]| 2019-01-15| B06F| Objections, documents and/or translations needed after an examination request according [chapter 6.6 patent gazette]| 2020-08-04| B06U| Preliminary requirement: requests with searches performed by other patent offices: procedure suspended [chapter 6.21 patent gazette]| 2020-12-29| B06A| Patent application procedure suspended [chapter 6.1 patent gazette]| 2021-06-08| B09A| Decision: intention to grant [chapter 9.1 patent gazette]| 2021-08-17| B16A| Patent or certificate of addition of invention granted [chapter 16.1 patent gazette]|Free format text: PRAZO DE VALIDADE: 20 (VINTE) ANOS CONTADOS A PARTIR DE 21/05/2010, OBSERVADAS AS CONDICOES LEGAIS. PATENTE CONCEDIDA CONFORME ADI 5.529/DF, QUE DETERMINA A ALTERACAO DO PRAZO DE CONCESSAO. |
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申请号 | 申请日 | 专利标题 US12/485,285|2009-06-16| US12/485,285|US8228046B2|2009-06-16|2009-06-16|Apparatus and method for operating an uninterruptible power supply| PCT/US2010/035756|WO2010147731A2|2009-06-16|2010-05-21|Power supply control| 相关专利
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