DISCONTINUOUS MODE PFC CONTROLLER HAVING A POWER SAVING MODULATOR AND OPERATION METHOD THEREOF
FIELD OF INVENTION
The present invention relates to a power factor correction (PFC) controller and an operation method thereof, and more particularly to a controller for a discontinuous mode PFC controller having a power saving modulator and operation method thereof.
BACKGROUND OF THE INVENTION Most power factor correction techniques incorporate and utilize a boost topology, which can be operated in either a continuous or a discontinuous inductor current mode at a fixed or a variable switching frequency. The continuous inductor current mode operated at a fixed switching frequency is used for higher power applications because of a low peak current applied and operated. For applications below 250 watts, the usage of the discontinuous inductor current mode operated with the variable switching frequency provides several advantages including small inductors, low costs, simple circuits, and zero current switching (ZCS). A pulse width of a power factor correction
(PFC) controller is controlled by a voltage error amplifier, which is compared to a saw-tooth waveform generated by the controller. The pulse width varies with line and load conditions, but should be maintained constant for a half of a line cycle. Therefore, it is necessary for the voltage error amplifier to have a lower frequency bandwidth that below the line frequency. The ZCS includes several advantages in applications. One advantage is that the inductor current must be released to zero before a next switching cycle is started which produces high switching efficiency. Since the change of the inductor current is equal to the peak inductor current and the current starts and returns to zero in each cycle, the current waveform has a triangular shape with an average value equal to one-half of the peak current multiplied by its time. Thus, the peak current is limited to exactly twice the average current. Since ZCS is switched right on the edging of the continuous and discontinuous current modes, the operation will be in variable switching frequency. Determined by the line input and output load, the pulse width of the switching signal is modulated, the switching frequency turns into low for heavy load conditions and
becomes high in response to the light load conditions. The low-bandwidth pulse width modulation (PWM) incorporates ZCS to provide a natural power factor correction for the input current. In recent prior arts, the ZCS varieties of the discontinuous current PFC controllers ; have been developed for the power factor correction control. Among them, the PFC controllers include the ST6561 of ST-Microelectronics, France; the MC34262 of ON-Semiconductor, Colorado; and the TDA4862 of Siemens, Germany. All of these controllers are designed to operate in a high frequency for a light load condition and/or no load condition. The switching losses of the power converter and the PFC booster are proportional to the switching frequency, in which the switching loss of the switching transistor, the power consumption of the snubber and the inductor losses are increased in accordance with a higher switching frequency. The drawback of the forgoing controllers is that under high frequency operation in the light load condition, it is difficult for the power converter to meet the energy conservation requirement, , especially for light load and no load conditions. Therefore, it is desirable to provide a PFC controller that maintains the PFC function and provides low power consumption for light load.
SUMMARY OF THE INVENTION
An objective of the invention is to provide a zero current switching (ZCS) discontinuous mode PFC controller to provide high efficiency PFC, as well as reducing the power consumption of PFC controller under light load conditions. Another objective of the invention is to eliminate the need of start-up resistors, which in turn, saves power. Another objective of the invention is to provide a method of limiting the maximum output power of the PFC controller for under- voltage protection. The present invention is related to a ZCS discontinuous mode PFC controller. When the line voltage is applied to the PFC converter, the feedback resistor and a parasitic diode of the controller startup the controller. Once the controller is turned on, a transistor will switch the feedback resistor to turn into the divider of the voltage feedback loop. For the PFC, an external resistor is used to determine the maximum
on-time of the switching signal, thus limit the maximum output power. While the switching signal is off, the inductor current will be released to zero before the next switching cycle is started which achieves ZCS. h order to decrease the switching frequency for light load conditions, an off-time delay is inserted right before the start of every switching cycle. The feedback voltage, which is derived from the voltage feedback loop, and the supply voltage are taken as the variable. The off-time delay is modulated to be the function of the feedback voltage and supply voltage. A threshold voltage is a constant that defines the level of the light load. A limit voltage defines the low-level of the supply voltage. Once the feedback voltage decreases and is lower than the threshold voltage, the off-time delay will be increased accordingly. When the supply voltage is lower than the limit voltage, the off-time delay is decreased to inhibit the decrease of the switching frequency, therefore, preventing a low supply voltage. The switching frequency is decreased in accordance with the decrease of the load. Consequently, this reduces the switching losses and power consumption for light load and no load conditions.
BRIEF DESCRIPTION OF THE DRAWINGS The accompanying drawings are included to provide a further understanding of the invention, and are incorporated in and constitute a part of this specification. The drawings illustrate embodiments of the invention and, together with the description, serve to explain the principles of the invention, h the drawings, Figure 1 is the schematic diagram of a discontinuous mode power factor correction (PFC) converter in accordance with a preferred embodiment of the present invention; Figure 2 shows the waveform of the discontinuous mode PFC converter of the preferred embodiment of the invention as shown in Figure 1; Figure 3, 4 and 5 are the schematic diagrams of the control circuit for discontinuous mode PFC converter of the preferred embodiment of the invention as shown in Figure 1.
DESCRIPTION OF THE PREFERRED EMBODIMENTS Figure 1 is the schematic diagram of a discontinuous mode power factor correction
(PFC) converter in accordance with a preferred embodiment of the invention. The
PFC converter includes a bridge 10, an inductor 20, a rectifier 30, and a capacitor 40.
For feedback operation, the PFC converter further includes a controller 100, capacitors
41 and 43, resistors 50, 51 and 53, a divider including a resistor 55 and a resistor 56, transistors 60 and 62 and a diode 75. Through the PFC converter an alternating current
(AC) line input is converted towards a direct current (DC) output No, in which an switching current 91 controls energy by switching AC input via the inductor 20, rectifier
30 and capacitor 40. The purpose of the PFC converter is to control a current IAC waveform of the AC line input as sinusoidal and maintain a phase of IAC as the same as the AC line input voltage NAc- Through the rectification of bridge 10, the VΓΝ is always positive with respect to the ground of the PFC converter. VIN(t) = VPsm(ωt); where Vp = z x V,N (in root mean square "RMS" values) The input current can similarly be expressed as: IIN(t) = Ipsin(ωt); where Ip=^2xIIN (RMS) The input power of the PFC converter is then given by: PIN=VPxIp/2 Taking the efficiency (η) into the equation, the output power is given by: Po=PιN χη P0=VPxIpxηl2 (1) Equation 1 can be expressed with regard to the input current IP = (2xP0)/(Vpxη) (2) At the boundary conduction mode, the peak switching current (IL-P) of the inductor 20 is exactly twice that of the average inductor current. J L_p = 2x p -P =^xP0)l(VPxη) (3) The switching current 91 can be shown in its time variant form. (0 = (4 P0 ) sin(ot) l(VP x 17) (4) The switching current 91 also can be solved for the on-time required to charge the
inductor L to the peak current such as I = L (di / dt). TON = -P x L/ Vp TON = (4 X P0 X L) /(Vp 2 x η) (5) T0FF = (IL-P * L)/(V0 - VP) TOFF = (4 P0 x L) l[(η x VP) x (V0 - VP )] (6) •* = * 0N "*" OFF Equation 5 can be expressed with regard to the output power. P0 = [Vp2 x η 1(4 x L)] x T0N (7) According to the foregoing Equation 7, it is noted that the output power is controlled by the on-time TON- By constraining the maximum on-time, the maximum output power will be limited, especially for under voltage protection such as brownout conditions. When the AC power is applied to the PFC converter, a DC voltage on the output voltage No is produced via the bridge 10, inductor 20, rectifier 30 and capacitor 40. Through a feedback resistor 55 and a parasitic diode 32 of the controller 100, the output voltage No charges the capacitor 41. A voltage N<χ in an input terminal NCC (hereafter denoted as "NCC") of the controller 100 is the voltage level of the capacitor 41. Once the voltage Ncc in the capacitor 41 is higher than a start-threshold voltage of the controller 100, the controller 100 will be turned on. At the instance the controller 100 turns on, a voltage such as 2 volts established at the RT output terminal (hereafter denoted as "RT") of the controller 100 will switch on the transistor 62. In the mean time, the resistor 56 is grounded. Resistors 55 and 56 form a divider of a feedback loop. Thus the joint resistance of the resistor 55 and 56 is connected to an FB input terminal (hereafter denoted as "FB") of the controller 100. The FB input terminal and a COM output terminal (hereafter denoted as "COM") act as an input terminal and an output terminal of an error amplifier 205, as shown in Figure 3 and will be described in details below. The capacitor 43 connected in between the FB and COM provides frequency compensation for a low frequency bandwidth that is below the line frequency. An OUT output terminal (hereafter denoted as "OUT") of the controller 100 outputs a switching signal to drive the transistor 60. After the controller 100 is turned on, an auxiliary winding of the
inductor 20 charges the capacitor 41 via the diode 75 disposed between the terminals NCC and DET and supplies the power for the controller 100. The voltage in the capacitor 41 is kept higher than a stop-threshold voltage to maintain the operation and prevent the voltage Ncc being at a low level within the controller 100. When the transistor 60 is driven on by the signal from the OUT of the controller
100, the inductor 20 is charged via the transistor 60. The resistor 53 senses a switching current 91 and is connected to an input terminal NS (hereafter denoted as "NS") of the controller 100. The signal from OUT would be switched off as long as a voltage level at the NS is higher than a limit voltage
which achieves a cycle-by-cycle current limit for the switching. While the transistor 60 is switched off by the signal from OUT, the energy stored in the inductor 20 is released to the output voltage No via the rectifier 30 by the discharge current 92. The waveform is shown in Figure 2. As soon as the discharge current 92 declines to zero, a zero voltage will be detected in the auxiliary winding of the inductor 20. An input terminal DET (hereafter denoted as "DET") of the controller 100 is connected to the auxiliary winding through the resistor 51, for detecting a zero current state. An off-time delay t
d is initiated once the zero current state is detected. After the off-time delay t
d, the controller 100 is able to start the next switching cycle. The resistor 50 connected from the RT of the controller 100 to the ground (GΝD) determines the maximum on-time of the switching signal, such as the signal from OUT terminal. Referring to Figures 3, 4 and 5, which are schematic diagrams of a preferred embodiment of the control circuit 100 for the discontinuous mode PFC converter of the invention as shown in Figure 1. Referring to Figure 3, first, the control circuit 100 includes a constant current source 315, a delay current source 300, an error amplifier 205, comparators 210, 211, 214 and 215, inverters 221, 222 and a buffer 226, ΝAΝD gates 223, 225, a NOR gate 227 and a SR flip-flip 228. A current I
R] generated by the constant current source 315 is applied to pull up a voltage level in the DET terminal of the controller 100. Once the voltage level of the DET is detected as a low signal, that is, the voltage level of the DET is lower than a first threshold voltage V
R1, the comparator 210 outputs a signal with a logic low state and then turns off the transistor 231 by the output of the NAND 223. An off-time delay t shown in Figure 2 is then initiated by switching off the transistor 231. A current I generated by the delay
current source 300 starts to charge the capacitor 241, and once the voltage level of the capacitor 241 is higher than a second threshold voltage Nr^, the comparator 211 will output a signal in a logic high state. By using the SR flip-flop 228, a switching signal PWM is then determined. The off-time delay can be stated as: T
d = (O
241 x V
R_ ) I I
d (8) where the C
24ι is the capacitance of the capacitor 241. The off-time delay t
d is modulated to be a function of the feedback voltage and Ncc voltage. The two inputs of the SR flip-flop 228 are respectively applied with the output of the comparator 211 and the feedback voltage from the FB terminal. The feedback voltage from the FB is applied to an input terminal of the error amplifier 205 and a reference voltage V
R is applied to the other input terminal of the error amplifier 205, and then a voltage Nco
M is generated therefrom. The voltage Nco
M is then applied to a positive input terminal of the comparator 214 and a signal SAW is applied to a negative input terminal of the comparator 214. The output of the comparator 214 is then applied to one input terminal of the ΝAΝD gate 223 and one input terminal of the ΝAΝD gate 225. The other input terminal of the ΝAΝD gate 225 is applied with a PULSE signal. The signals SAW and PULSE will be described in detail later. The output of the ΝAΝD gate 225 is then applied to one input terminal of the NOR gate 227. The other input terminal of the NOR gate 227 is applied with output of the inverter 222. The output of the inverter 222 is a signal inverted from the output of the comparator 215. One input terminal of the comparator 215 is applied with a voltage from the NS terminal of the controller 100, as shown in Figure 1. Another input terminal of the comparator 215 is applied with a third threshold voltage N^. By adjusting the voltage levels of the Nco
M, the SAW signal and the PULSE signal, the off-time delay can be modulated to be a function of the feedback voltage by the SR flip-flop 228. Referring to Figure 3, the current I
d from the delay-current 300 can be generated in according to the load condition. The circuit in Figure 5 includes a first current mirror composed of transistors 273, 274 and 275, a second current mirror composed of transistors 277 and 278, and a third current mirror composed of transistors 291 and 292. A transistor 270 and a resistor 50 generate the mirror current in the first current mirror. A gate terminal of the transistor 270 is coupled to the output of an op-amplifier 260. A positive input terminal of the op-amplifier 260 is applied with a seventh threshold
voltage V
R7 and a negative input terminal of the op-amplifier 260 is coupled to a source terminal of the transistor 270 and the resistor 50. The mirror current of the first current mirror is N
R7 / R
50 and two currents Iτι and Iτ
2 are respectively generated therefrom according to the width/length ratios of the transistors 274 and 275 compared with the transistor 273. Therefore, the current Iτι is equal to (N
R7 / R
50)
• (Ν
27 / N
7 ), where the N274, N
273 are respectively the width/length ratios of the transistors 274 and 273. The current I
T2 is equal to (V
7 / R
50)
• (N
275 / N
2 ), where the N
275, N
273 are respectively the width/length ratios of the transistors 275 and 273. The mirror current in the second current mirror is generated by a transistor 271. and a resistor 282. A gate terminal of the transistor 271 is coupled to the output of an op-amplifier 261. A positive input terminal of the op-amplifier 261 is applied with the Nco
M, as shown in Figure 3, and a negative input terminal of the op-amplifier 261 is coupled to a source terminal of the transistor 271 and one terminal of the resistor 282. The other terminal of the resistor 282 is coupled to the output terminal and a negative input terminal of an op-amplifier 262. A positive input terminal of the op-amplifier 262 is applied with a fifth threshold voltage N
5. The mirror current of the second current mirror can be denoted as (NcoM - NR
5) / 2
82, where the R
282 is the resistance of the resistor 282. The mirror current in the third current mirror is generated by a transistor 293 and a resistor 288. A gate terminal of the transistor 293 is coupled to the output of an op-amplifier 264. A positive input terminal of the op-amplifier 264 is applied with a sixth threshold voltage N
6 and a negative input terminal of the op-amplifier 264 is coupled to a source terminal of the transistor 293 and one terminal of the resistor 288. The other terminal of the resistor 288 is coupled to the output terminal and a negative input terminal of the op-amplifier 265. A positive input terminal of the op-amplifier 265 is applied with a voltage generated from the Ncc attenuated by resistors 285 and 286. The mirror current of the third current mirror can be denoted as (V
R6 - αNcc) / R
288, where the R
288 is the resistance of the resistor 288, α = R
286 / (R
286 + R
85), R
286 and R
285 are respectively the resistance of the resistors 286 and 285. The current I
d for the delay current source 300, as shown in Figure 3, can be obtained by adding a left mirrored current I
a generated from the mirror current of the second current mirrored by the transistor 278 compared with the transistor 277 and a
right mirrored current I generated from the mirror current of the third current mirror by the transistor 291 compared with the transistor 292. The fifth threshold voltage V
R5 is a constant that defines a level of the light load. The sixth threshold voltage V
R6 is a limit voltage for defining a low-level of the Ncc voltage. Once the decreasing voltage Nco
M is lower than the fifth threshold voltage N
R5, the off-time delay will be increased accordingly. When the attenuated Ncc voltage is lower than the sixth threshold voltage N
R6, the off-time delay is decreased to inhibit the decrease of the switching frequency therefore prevents a low Ncc voltage. The switching frequency is decreased in accordance with the decrease of the load. Consequently, this reduces the switching losses and power consumption for light load and no load conditions. The formulae are described as follows:
= WCOM ~ VRS 282 ] x Kx + [(VR6 - Vcc ) I R288 ] x K _ (9) . .. a - R286 /(R286 + R285 ) K I = N 278 IN 277 ' ■ K ■"- 2 = N J V 291 I ' N J V 292 ' ■ Id ≤ IT2 Where /„ = (VR1 1 R50 ) x (N275 / N273 ) /„ = (VR1 /R50) (N274 /N273) (10) Referring to Figure 4, which shows a circuit of a preferred embodiment of the signals SAW and PULSE as shown in Figure 3. The circuit includes a comparator 217, a ΝAΝD gate 250, a transistor 232, a current source 310, a capacitor 242, and a SR flip-flop 229. The current Iτι of the current source 310 is shown in Figure 5. The switching signal PWM is applied to one input terminal of the ΝAΝD gate 250. The output terminal of the ΝAΝD gate 250 is applied to a gate terminal of the transistor 232. The transistor 232 is turned off once the switching signal PWM is high. The current Iτι of the current source 310 starts to charge the capacitor 242 and generates a saw-tooth waveform SAW in the capacitor 242. The turned-off switching signal PWM will turn on the transistor 232 and then discharge the capacitor 242. The SAW signal is applied to a negative input terminal of the comparator 217 and a fourth threshold voltage VR4 is
applied to a positive input terminal of the comparator 217 and then the output terminal of the comparator 217 is the PULSE signal, which is applied to the SR flip-flop 229. The output of the SR flip-flop 229 is applied to the other input terminal of the NAND gate 250. As shown in Figure 3, if the output of the error amplifier 205, VCOM, is lower than the voltage of the SAW signal or the voltage from the NS terminal is higher than the third threshold voltage Nry, which is an over-current threshold voltage in an over-current condition, then the switching signal PWM will be turned off. If the switching signal PWM keeps high, then the saw-tooth waveform of the SAW signal will be discharged as long as the voltage level of the SAW signal is higher than the fourth threshold voltage NR4. Therefore the maximum on-time of the switching signal PWM is determined by (C242 x NR.4) / Iτι, where the C242 is the capacitance of the capacitor 242. >From Equation 10, the ITι is equal to (NR7 / R50) x (Ν274 / N273), and the maximum on-time of the switching signal PWM is equal to (R50 x C242 x NR4) / [NR7 χ (Ν2 4 / N2 3)]. Therefore, the maximum on-time of the switching signal PWM is determined in accordance with the resistor 50, as shown in Figure 1. The foregoing description can be expressed as: ^ON-MAX ~ (^242 X " R / ' T\ (U) = ( so x 42 x VR )I[VR1 x (N274 INm)_ (12) where TOΝ-MAX is the maximum on-time of the switching signal PWM. Due to the maximum on-time of the switching signal PWM is limited, the switching devices of the PFC converter is protected from over-stress damage for under-voltage conditions. According to the ZCS and the discontinuous mode PFC conversion of the invention, the next switching cycle is started at the boundary of zero inductor current state, wherein the off-time delay td is almost zero. The energy is given by: ε = L χ I2 /2 (13)
The power supplied by the PFC boost converter can be expressed as: P0 = [Vp 2 η x TON 2 l(4x L x T) (14) T = TON + OFF is shown in Equations 5 and 6. When the load of the PFC converter is decreased in the light load condition, the off-time delay td is increased
accordingly and inserted before the start of the next switching cycle. Hence, the switching period T of the switching signal is extended as: T = T0N + TOFF + td (15) The switching frequency of the switching signal is thus decreased in light load and no load conditions. Therefore, the standby power is reduced. Furthermore, the feature of the off-time delay helps to keep the PFC function and maintain a stable output voltage No (No = Po / Io) of the PFC converter in light load conditions. Referring to
Equation 14, a very small TON pulse width should be generated for an extremely light load condition. The extremely short TON increases the difficulty of the PFC converter design. The limit on the short-pulse width of the Ton limits the performance of the power converter, hence, a dummy load has to be added at the output of the PFC converter to obtain a stable output voltage No. According to equation 14 and 15, it is shown that the insertion of the off-time delay td of the invention extends the switching period T and eliminates the need of an extremely short TON- A stable output voltage No is maintained and no dummy load is needed, which saves the power consumption in the PFC converter. It will be apparent to those skilled in the art that various modifications and variations can be made to the structure of the present invention without departing from the scope or spirit of the invention. In view of the foregoing, it is intended that the present invention cover modifications and variations of this invention provided they fall within the scope of the following claims and their equivalents.