irplpfc1 - International Rectifier

Application Note AN-1179
IRPLPFC1
90-265VAC PFC Pre-regulator
By Peter B. Green
Table of Contents
Page
1. Introduction ......................................................................................2
2. Power Factor and THD.....................................................................3
3. PFC Functional Description..............................................................6
4. Design Equations .............................................................................11
5. Factors affecting PF and THD..........................................................14
6. PCB Layout Considerations .............................................................16
7. Bill of Materials.................................................................................19
8. Test Results .....................................................................................21
Safety Warning!
The IRPLPFC1 power factor correction pre-regulator is based on a non-isolated Boost SMPS
circuit topology. The output is nominally 420VDC. When operating the output produces potentially
dangerous voltages! Additionally short circuiting or overloading the output will damage the board.
The IRPLPFC1 demo board should be handled by qualified electrical engineers only!
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EVALUATION BOARD - IRPLPFC1
1. Introduction
Many offline applications require power factor correction circuitry in order to
minimize transmission line losses and stress on electrical generators and
transformers created by high harmonic content and phase shift. Electronic
appliances often incorporate switching power supplies (SMPS) which include
capacitive filter circuitry followed by a bridge rectifier and bulk capacitor supplying
a load. Without power factor correction circuitry a SMPS draws a high peak
current close to the line voltage peak and almost no current over much of the
cycle, resulting in a power factor of around 0.5 with high total harmonic distortion.
Power factor correction circuitry can be added to enable the appliance to draw a
sinusoidal current from the AC line with negligible phase shift and very low
harmonic distortion. This represents the best type of load for the power
transmission grid so that power can be supplied without creating additional
conductive losses in transmission lines or additional burden on transformers and
generators. Costs to electricity providers are therefore reduced, which passes
savings on to the consumer. The trend towards more efficient power utilization
for offline appliances, power supplies and lighting converters makes high power
factor and low total harmonic distortion of the line input current (THDi) desirable.
Standards for power quality exist such as EN61000-3-2 in which specific current
harmonic limits are detailed for various different applications. Compliance with
class C limits is required for electronic lighting ballasts rated at 25W or above.
Market preferences often require LED converters and light fixtures to offer good
performance at even lower power ratings.
For a product incorporating active power factor correction a THDi of less than
20% over a wide input voltage range, normally 100VAC to 305VAC is expected.
In many cases THDi of less than 10% can be achieved over much or all of this
voltage range.
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Important Safety Information
The IRS2500 based PFC pre-regulator does not provide galvanic isolation of the
output from the line input. Therefore if the system is supplied directly from a
non-isolated input, an electrical shock hazard exists. The DC output voltage is
high enough to produce a potentially lethal electrical shock therefore appropriate
care should be taken when working on the IRPLPFC1 board.
It is recommended that for laboratory evaluation that the IRPLPFC1 board be
used with an isolated AC or DC input supply. The IRS2500 series Boost
topology is suitable only for front end applications where isolation is either not
necessary or provided elsewhere in the system.
In addition since the IRPLPFC1 is a Boost converter there is no short circuit
protection therefore care must be taken not to short circuit or overload the
output.
2. Power Factor and THD
THD is defined as the RMS value of harmonic distortion from all components of
an AC signal excluding the fundamental, expressed as a percentage of the RMS
of the fundamental. In other words it quantifies the amount by which the signal
deviates from a pure sinusoid;
∞
THD =
∑ An
n =2
A1
2
=
( ARMS − A1
2
A1
where A1 is the RMS amplitude of the fundamental and ARMS is the total RMS
value of the complete current signal. THD of the current is often referred to as
THDi to differentiate it from the voltage THD.
It should be noted that THDi is not the only quantity contributing to power factor
(PF) reduction since phase shift between current and voltage inputs are not
factored into the THD calculation. Power factor is defined as the ratio of the real
power, which is utilized by the load, to the apparent power which also includes
reactive and distortion power. Power factor (PF) includes displacement power
factor resulting from phase displacement created by circuit reactances and
distortion power factor created by harmonics.
Figure 1. Power Vector Diagram
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The general formula for power factor is:
PF =
PRMS
V RMS ⋅ I RMS
where PRMS is the real power consumed by the load.
The displacement power factor is given the formula:
DPF = COS(φ )
where Ф is the phase shift between the voltage and sinusoidal current.
The following formula gives the distortion power factor:
DF =
1
1 + THD 2
The following formula combines these to give the total power factor:
PF =
COS (φ1 )
1 + THD 2
where Ф1 refers to the phase shift between the voltage and the fundamental
component of the current and THD is expressed as a fraction.
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Figure 2: IRPLPFC1 Schematic
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3. PFC Functional Description
Figure 2 shows the schematic for PFC pre-regulator based on a critical
conduction mode Boost circuit. The IRS2500 pin out conforms to most industry
standard power factor controllers and can be used as a drop in replacement for
alternative parts in many applications and with minor modifications in many more.
The IRPLPFC1 Boost PFC pre-regulator circuit consists of an EMI filter followed
by a bridge rectifier which provides a full wave rectified voltage at the input to the
Boost inductor LPFC. C3 provides an essential path for the circulating high
frequency switching current. The EMI filter consisting of C1, L1, C2 and L2
provides reduction of common mode and series mode noise being conducted
back onto the AC line. A series mode filter is necessary in PFC circuits operating
in critical conduction mode since these produce higher current ripple than
continuous mode systems. At power levels below 100W the benefits of critical
conduction mode in the form of reduced switching losses outweigh the
disadvantage of more filtering.
In critical conduction mode CrCM (also known as transition or boundary mode)
the PWM gate drive signal to MPFC maintains a constant on time during the line
cycle apart except where additional on time is added near the zero crossing. The
off time varies during the AC line cycle. Each new switching cycle begins when
the energy stored in LPFC has been fully transferred to the output therefore the
off time varies during the AC line cycle becoming longer at the peak.
The on and off times not taking into account the additional on time modulation
can be calculated by the following formulae:
L.IL ( pk )
2 .Vin ( rms )
L.IL ( pk ). sin θ
=
Vout − 2 .Vin ( rms ). sin θ
TON =
TOFF
Where ILpk is the peak current in the inductor and Boost MOSFET Q1 at the
peak of the AC line cycle and θ is the phase angle of the instantaneous AC line
voltage, which varies over the cycle.
A feedback loop regulates the output voltage by adjusting the PWM on time. This
takes place gradually over many line cycles so that the on time remains
effectively constant over the period of a single line half cycle and therefore the
input current follows the shape of the input voltage remaining sinusoidal.
When the MOSFET switch Q1 is turned on, the inductor LPFC is connected
between the rectified line input (+) and (-) causing the current in LPFC to
increase linearly. When Q1 is turned off, LPFC is connected between the
rectified line input (+) and the DC bus capacitor CPFC through diode DPFC. The
stored energy in LPFC is transferred to the output, supplying current into CPFC.
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Q1 is turned on and off at frequencies ranging from 30kHz to several hundred
kHz depending on the value of LPFC and the power throughput. The voltage at
CPFC charges up to a specified level and the voltage feedback loop of the
IRS2500 regulates the output by continuously monitoring the DC output and
adjusting the on-time of MPFC as needed. If the output voltage is too high the
on-time is decreased and if it is too low the on-time is increased. This negative
feedback control loop operates with a slow loop speed relative to the AC line
frequency and a low loop gain such that the average inductor current smoothly
follows the low-frequency line input voltage to obtain high power factor and low
THD.
V, I
t
Figure 3: Sinusoidal line input voltage (solid line), triangular PFC Inductor
current and smoothed sinusoidal line input current (dashed line) over one halfcycle of the AC line input voltage.
Adjustment of the output voltage can only occur over several line cycles. With a
fixed on-time and an off-time determined by the inductor current discharging to
zero, the switching frequency is free-running and constantly changing from a high
frequency near the zero crossing of the AC input line voltage, to a lower
frequency at the peaks (Figure 3) due to the much longer off time.
When the line input voltage is low (near the zero crossing) the inductor current
will rise to a relatively low level so the discharge time will be short. When the
input line voltage is high (near the peak), the inductor current will charge up to a
much higher level and the discharge time will be longer.
The PFC control circuit of the IRS2500 U1 shown in the simplified schematic of
figure 4, includes six control pins: VBUS, COMP, ZX, OUT, VDC and OC. The
VBUS pin measures the DC bus voltage through an external resistor voltage
divider. The error amplifier output appears at the COMP pin voltage, which
determines the on-time and sets the feedback loop response speed with an
external RC integrator or other compensation network. The ZX pin detects when
the inductor current discharges to zero each switching cycle using a secondary
winding from the PFC inductor. The OUT pin is the low-side gate driver output for
the external MOSFET. The VDC pin senses the line input cycle providing phase
information to control the on time modulation described in the next section. The
OC pin senses the current flowing through MPFC and performs cycle-by-cycle
over-current protection.
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Figure 4: IRS2500 simplified PFC control circuit.
The VBUS pin is compared with a precision internal 2.5V reference voltage for
regulating the DC output voltage. The feedback loop error amplifier increases or
decreases the COMP pin voltage. The resulting voltage on the COMP pin sets
the threshold for the charging of the internal timing capacitor shown in Figure 5
and therefore determines the on-time.
VCC
OC 4
VOCTH
COM
6
8
200 ns
Blank Time
UVLO
VBUS 1
VCLAMP
OVP
VVBUS
VCC
VVBUSOV
7
COMP 2
VDC
ON TIME
MODULATOR
3
S
Q
R
Q
CT
S
Q
OUT
Watchdog
Timer
R1
R2 Q
ZX 5
VZXCLAMP
VZX
Figure 5: IRS2500 Internal Block Diagram.
The off-time is determined by the time it takes the LPFC current to discharge to
zero. The zero current level is detected by a secondary winding on LPFC that is
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connected to the ZX pin through an external current limiting resistor RZX. This
winding typically has a 1:10 turns ratio relative to the main winding. A positivegoing edge exceeding the internal threshold VZX+ signals the beginning of the
off-time. A negative-going edge on the ZX pin falling below VZX- occurs when
the LPFC current discharges to zero signaling the end of the off-time when the
gate drive output OUT transitions high again (Figure 12). The ZX pin is internally
biased to 1V so that a positive current must be supplied to the ZX input to set the
ZX detector and a negative current must be supplied to indicate all of the energy
has been discharged and the winding voltage polarity has reversed. A wide
hysteresis prevents false triggering by ringing oscillations.
The cycle repeats indefinitely until the IRS2500 is disabled through an overvoltage condition on the DC bus or if the negative transition of ZX pin voltage
does not occur. Should the negative edge on the ZX pin not occur, the gate drive
output will remain off until the watch-dog timer forces a re-start. The watch-dog
pulses occur every 300-400us (tW) indefinitely until a correct positive and
negative-going signal is detected at the ZX pin and normal operation is resumed.
Should the OC pin voltage exceed the VOCTH over-current threshold during the
on-time the gate drive output will turn off. The circuit will then wait for a negativegoing transition on the ZX pin or a forced turn-on from the watch-dog timer to turn
the output on again.
ILPFC
...
OUT
...
ZX
...
VOCTH
OC
...
Figure 6: Inductor current, OUT pin, ZX pin and OC pin timing diagram.
A fixed on-time over an entire cycle of the line input voltage produces a peak
inductor current that naturally follows the sinusoidal shape of the line input
voltage. The smoothed, averaged line input current is in phase with the line input
voltage for high power factor but some harmonic distortion of the current
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remains. This is due to cross-over distortion of the line current near the zerocrossings of the line input voltage. To achieve lower harmonics that are
acceptable for compliance with international standards and general market
requirements, an additional on-time modulation circuit has been added to the
PFC control. This IRS2500 dynamically increases the on-time as the line input
voltage nears the zero-crossings (Figure 7). This causes the peak LPFC current,
and therefore the smoothed line input current, to increase near the zerocrossings of the line input voltage. This reduces the amount of cross-over
distortion in the line input current which reduces the current THD.
On time modulation is controlled by sensing the full wave rectified voltage at the
bridge rectifier output through a resistor divider (RDC1, RDC2 in figure 4). This is
scaled such that the peak voltage will be close to 1V at 120VAC and 3V at
265VAC. This function can be disabled if necessary by connecting a 10K resistor
from pin 3 to VCC in place of the input signal.
ILPFC
0
OUT
pin
0
near peak region of
rectified AC line
near zero-crossing region
of rectified AC line
Figure 7: On-time modulation circuit timing diagram.
The IRS2500 incorporates both static and dynamic overvoltage protection. Static
over voltage protection monitors the feedback voltage at the VBUS pin and
disables the gate drive output if this voltage exceeds the target voltage by 8%.
This is activated by an internal comparator set to detect a threshold of 2.7V,
which is 8% above the regulation threshold of 2.5V.
However, under startup condition or when a load is removed from the output the
error amplifier output voltage at the COMP pin swings low. Since the
compensation capacitor CCOMP is connected from this output back to the VBUS
input a current will flow during the COMP voltage transition. This pulls down the
VBUS voltage, which allows the output voltage to exceed the desired regulation
level during the transition and results in an overshoot before the voltage at the
VBUS input exceeds the regulation threshold.
In order to compensate for this effect, the IRS2500 includes dynamic detection of
the error amplifier output current. During a swing in the negative direction the
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error amplifier output sink current peaks at a much high level than during steady
state operation. This current surge is internally detected to trigger the overvoltage
protection circuitry disabling the PWM output until the error amplifier output has
settled to a new level. This prevents the output voltage from overshooting the
desired level by a significant amount under the transient conditions described.
For this reason the loop should be designed such that voltage ripple at COMP is
minimized during steady state operation to avoid false tripping of the dynamic
overvoltage protection.
The IRPLPFC1 board provides the VCC supply to IC1 by means of a charge
pump supplied from the auxiliary winding consisting of R3,C4,D3 and D4. The
initial startup voltage is supplied through Rstart1,Rstart2 and Rstart3. Since
CDC1 and CDC2 are quite large there is a delay at switch on before the VCC
voltage comes up and the PFC circuit begins to operate. This delay can be
several seconds at low line voltages. In an application the VCC supply can be
derived from various different means and the startup delay can also be reduced.
Q2, R5 and Dz1 form a regulator to limit the VCC voltage since the voltage from
the auxiliary winding varies considerably with VAC.
4. Design Equations
Step 1: Calculate PFC inductor value:
LPFC =
2
(VBUS − 2 ⋅ VAC MIN ) ⋅ VAC MIN
⋅η
2 ⋅ f MIN ⋅ POUT ⋅ VBUS
[Henries]
where,
VBUS = DC bus voltage
VAC MIN = Minimum RMS AC input voltage
= PFC efficiency (typically 0.95)
η
f MIN
= Minimum PFC switching frequency at minimum AC input voltage
POUT
= Output power
Step 2: Calculate peak PFC inductor current:
iPK =
2 ⋅ 2 ⋅ POUT
VACMIN ⋅η
[Amps Peak]
Note: The PFC inductor must not saturate at i PK over the specified ballast
operating temperature range. Proper core sizing and air-gapping should
be considered in the inductor design.
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Referring to the designators in figure 4:
Step 3: Calculate PFC over-current resistor ROC value:
ROC =
VOCTH
iPK
where VOCTH = 1.1V
[Ohms]
ROC power rating can be approximated:
2
PROC
⎛ POUT ⎞
⎟⎟ × ROC
≥ ⎜⎜
.
η
VAC
MIN
⎠
⎝
[Watts]
Step 4: Calculate start-up resistor RVCC value:
RVCC <
VAC MIN
IQCCUV
PRVCC >
[Ohms]
2
V ACMAX
RVCC
[Watts]
RVCC is often comprised of several series resistors (Rstart1, Rstart2 and
Rstart3 in the IRPLPFC1 circuit) in order to withstand the high voltage.
Step 5: Calculate VBUS feedback resistor divider network:
RBUS1 is often comprised of two series resistors (RBUS1A and RBUS1B
in figure 4, Rb1 and Rb2 in the IRPLPFC1 circuit) in order to withstand the
high voltage.
Select an initial value of 10K for RBUS2 (Rb3 in the IRPLPFC1 circuit)
RBUS1 = (VBUS − 2.5) ×
RBUS 1 A = RBUS 1B =
10000
2.5
[Ohms]
RBUS 1
2
[Ohms]
Choose the nearest preferred value for RBUS1A and RBUS1B.
Then re-calculate RBUS2:
RBUS 2 =
2.5 × ( RBUS 1 A + RBUS 1B )
VBUS − 2.5
[Ohms]
Then choose the nearest E96 1% tolerance value for RBUS2.
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Step 6: Calculate VDC resistor divider network:
RDC1 is often comprised of two series resistors (RDC1A and RDC1B in
figure 4, Rin1 and Rin2 in the IRPLPFC1 circuit) in order to withstand the
high voltage.
Select an initial value of 10K for RDC2 (Rin3 in the IRPLPFC1 circuit)
R DC 1 = ( 2.V ACMIN − 1) × 10000
[Ohms]
Choose the nearest preferred value for RDC1A and RDC1B.
Then re-calculate RDC2:
RDC 2 =
RDC1 A + RDC1B
[Ohms]
2.V ACMIN − 1
Then choose the nearest E96 1% tolerance value for RDC2.
Step 7: Calculate COMP capacitor:
CCOMP should be selected to roll off the gain of the error amplifier at
approximately 20Hz.
CCOMP =
1
2π × 20 Hz × RBUS 2
[Farads]
Choose the nearest preferred value for CCOMP shown in figure 4.
A simple integrator network is normally sufficient for compensation in most
PFC pre-regulators. For added flexibility the IRPLPFC1 board includes a
single pole at 16Hz and a single zero at 1600Hz. This allows the gain to
remain flat between these two frequencies. This gain is determined by the
value of Rgm. Replacing Rgm with a zero Ohm resistor will convert the circuit
to a simple integrator that crosses zero gain at 16Hz.
Step 8: Calculate RZX resistor:
Choose Izx as 0.5mA and assume ZX winding maximum voltage VZX of
20V at the ZX winding as an approximation. If the actual VZX is higher
than 20V use the true value.
VZX
[Ohms]
I ZX
Choose the next lowest preferred resistor value for RZX.
RZX ≤
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5. Factors affecting PF and THD
The PFC pre-regulator circuit described above draws a current from the line input
which follows the shape of the voltage, however the following points should be
considered when optimizing circuit performance:
1. Phase shift produced by filter capacitors.
The capacitors C1 and C2 used in the EMC filter draw AC current from the line
input, which leads the voltage by 90º. The magnitude of this reactive current is
dependent on the capacitor values and the AC line input voltage. This is one
reason why the power factor always drops as line input voltage increases. For
this reason these values should be kept as small as possible while making sure
the input filter is adequate for EMC compliance.
2. Phase shift produced by the bridge capacitor.
The bridge capacitor C3 also causes some phase shift since the voltage across it
is full wave rectified.
This should also be kept to a minimum though it must be sufficient to provide a
high frequency AC current source for the switching regulator. The value of C3
also affects EMI.
3. Cross over distortion produced by the bridge capacitor.
C3 also contributes to cross over distortion while C1 and C2 do not. The circuit
can be considered as a resistive load and therefore it is clear that as the AC line
input voltage passes through each zero crossing, C3 needs to discharge through
the load. Depending on the storage capacity of C3 and the load, the voltage on
C3 never discharges completely to zero at each zero crossing always
maintaining a residual voltage. This problem becomes worse in systems where
the load is variable such as a dimmable electronic lighting ballast. As the load is
reduced the residual voltage on C3 increases. Since this voltage does not reach
zero, when the AC line input voltage drops below the minimum voltage at C3
there is no current drawn from the line input resulting in the characteristic
crossover distortion dead band shown on the input current waveform in figure 8.
It should be noted that the two diode drops in the bridge rectifier B1 also
contribute to cross over distortion to a small extent.
Crossover distortion can never be completely eliminated for these reasons,
however by choosing the value of C3 to provide the best tradeoff and by the on
time modulation provided by the IRS2500, this can be minimized.
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Figure 8: Line input and current in a typical PFC pre-regulator
4. Minimal energy transfer at the zero crossing.
At low line input voltage levels there may be insufficient energy stored in the
Boost inductor LPFC to provide enough voltage at the drain of MPFC to forward
bias the output diode DPFC. This is due to parasitic capacitances in the windings
of LPFC as well as the drain to source capacitance of the MOSFET switch. This
being the case it is necessary for the control IC to compensate for this by
increasing the MOSFET on time when the voltage approaches zero in order to
draw more current. This on time modulation has already been described. The line
input voltage is generally detected through the divided input signal provided at
pin 3 (VDC). It should be noted here that the residual voltage across C3 will be
also be divided down through Rin1, Rin2 and Rin3 so that it also appears at pin
3, which prevents the IC from detecting the input voltage below the level of the
residual voltage. In order to limit this problem, the IRS2500 is designed to
produce sufficient on time modulation to discharge C3 as close to zero as
possible and introduce this modulation before the residual voltage level is
reached.
5. Ripple at the error amplifier output (COMP)
The output bus voltage from the PFC pre-regulator circuit will always contain
some ripple at twice the line frequency (∆VOUT) superimposed on top of the
regulated DC output. The magnitude of ∆VOUT depends on the magnitude of the
output storage capacitor CBUS. Since the output voltage is divided and fed back
to the inverting input of the error amplifier, a component of ripple will also be fed
to the input and compared with the internal 2.5V reference of the IRS2500. This
may result in a component of ripple appearing at the error amplifier output
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(COMP) which determines the PWM on time. It is necessary for the
compensation capacitor CZ to be large enough to roll off the error amplifier gain
at a frequency well below twice the line frequency in order to reduce this ripple to
a very small level. Ripple at the COMP output results in modulation of the on time
causing distortion of the current waveform and should therefore be eliminated as
far as possible without slowing down the loop response too much.
6. Delay before next switching cycle
In critical conduction mode an auxiliary wining on the Boost inductor provides a
signal to the ZX (zero crossing) pin of the controller to signal when the energy
from the inductor has been fully transferred to the output by transitioning from
high to low. When this transition is detected the PWM output drive goes high to
start the next cycle, however if there is delay then the converter is actually
operating in discontinuous mode due to the delay. This can cause some
distortions in the current waveform. Delay is minimized in the IRS2500.
Capacitors should not be added at the ZX pin.
6. PCB Layout Considerations
Figure 9: IRPLPFC1 PCB Bottom Layer
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Figure 10: IRPLPFC1 PCB Top Layer
For correct operation of the IRS2500, the PCB has been designed to avoid noise
coupling to the control inputs and ground loops according to the layout
recommendations listed in the IRS2500 datasheet:
1. As a general rule the circuit signal and power grounds should be
separated and joined together at one point only. The signal ground should
be a star point located close to the COM pin of the IRS2500.
2. A noise decoupling capacitor CVCC is located between the VCC and
COM pins of the IRS2500 located as close to the IC as possible.
3. All traces to the VBUS input have been kept as short as possible. This
means that resistors and capacitors that are connected to this input
(Rb2,Rb3,Cp and Rgm) are be located as close to the IRS2500 as
possible. The voltage feedback divider resistor (Rb3) connected to COM is
be connected to a signal ground close to the COM pin.
4. Traces carrying high voltage switching signals such as those connected to
the MOSFET drain or gate drive signals are not be located close to traces
connected directly to the VBUS input.
5. The divider network resistor (Rin2 and Rin3) and filter capacitor (CVdc)
connected to the VDC input of the IRS2500 are located as closely to the
IC as possible with the grounded end connected to the circuit signal
ground.
6. The over current detection filter resistor (ROC) and capacitor (COC)
should be located as close to the IRS2500 as possible with COC
connected to the circuit signal ground.
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7. The zero crossing detection resistor Rzx is located close to the IRS2500 if
possible to prevent possible noise appearing at this input.
Figure 9 and 10 show the IRPLPFC1 PCB layout where the IRS2500 is located
on the bottom side of the PCB. The bottom side traces are shown in blue and the
top side traces in red. The circuit power ground can be seen at the CPFC
negative (COM1,COM2) node with the signal ground located around IC1 from
Rb3 to CVdc which is connected to Rin3, COC and CVCC and to pin 6 (COM) of
IC1 (D5 is not fitted). The signal ground traces from IC1 pin 6 also connect to the
LPFC ground pin and VCC capacitors CDC1 and CDC2. A ground plane on the
top copper layer also connects to the signal ground although this is not essential.
The power ground begins at the junction of CBUS and the shunt resistor RsPFC
which carries the high current from the switching MOSFET Q1 and the output
return current back to the AC line through the bridge B1. C3 is connected
between the power ground and rectified DC voltage from B1.
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7. Bill of Materials
Item
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
Description
IC, PFC Controller
Bridge Rectifier,
600V, 4A
Diode, 600V, 3A,
Fast recovery
Diode, 600V, 3A,
Fast recovery
Diode, 75V, 0.15A,
SOD-80
Diode, Zener 18V,
500mW, SOD-80
MOSFET, 650V, 0.25
Ohm, TO-220
Transistor, NPN,
40V, 200mA, TO-92
Capacitor, 220nF,
275VAC, Radial 0.6"
Capacitor, 470nF,
400V, Radial 0.6"
Capacitor, 0.1uF,
50V, 10%, 1206
Capacitor, 33uF,
35V, Electrolytic
Radial, 105C
Capacitor, 100uF,
25V, Electrolytic
Radial, 105C
Capacitor, 1uF, 25V,
10%, 1206
Capacitor, 1nF, 50V,
10%, 0805
Capacitor, 470pF,
100V, 5%, 0805
Capacitor, 1uF, 25V,
10%, 0805
Capacitor, 10nF,
50V, 10%, 0805
Capacitor, 56uF,
450V, Electrolytic
Radial, 105C
Inductor, 3.3mH,
1.5A, common mode
Inductor, 1mH, 1A,
Axial
Inductor, 500uH
Resistor, 22Ohm,
0.25W, 5%, 1206
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Part Number
IRS2500S
GBU4J
Manufacturer
International
Rectifier
Micro
Commercial
Quantity
Reference
1
IC1
1
B1
STTH3L06S
STMicro
1
DPFC
RS3JB-13-F
Diodes Inc
1
D1
DL4148-TP
Micro
Commercial
4
D3,D4,D5
,DgPFC
FLZ18VC
Fairchild
1
Dz1
IPP60R250CP
Infineon
1
Q1
2N3904TF
Fairchild
1
Q2
ECQ-U2A224ML
PanasonicECG
2
C1,C2
QXK2G474KTP
Nichicon
1
C3
C3216X7R1H104K
TDK
1
C4
EKZE350ELL300M
E11D
United
Chemi-Con
1
CDC1
EKZE250ELL101M
F11D
United
Chemi-Con
1
CDC2
C3216X7R1E105K
TDK
1
CVCC1
C2012X7R1H102K
TDK
1
CFB1
C2012COG2A471J
TDK
1
COC
C2012X7R1E105K
TDK
1
CZ
C2012X7R1H103K
TDK
2
CP,CVDC
EEU-EE2W560
PanasonicECG
1
CPFC
B82721A2152N1
Epcos
1
L1
RL-1282-1000
Renco
1
L2
PFC-13500-01
Precision Inc
PanasonicECG
1
LPFC
1
R3
ERJ-8GEYJ220V
AN-1179
19
24
Resistor, 2.2kOhm,
0.25W, 5%, 1206
ERJ-8GEYJ222V
PanasonicECG
1
R5
25
Resistor, 750kOhm,
0.25W, 5%, 1206
ERJ-8GEYJ754V
PanasonicECG
4
RB1,RB2,
RIN1,RIN
2
RC0805FR078K87L
Yageo
1
RB3
ERJ-6GEYJ103V
PanasonicECG
1
RGM
RC0805FR0712K7L
Yageo
1
RIN3
3
RL1,RL2,
RL3
1
ROC
1
RPFC1
1
RSPFC
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
Resistor, 8.87kOhm,
0.125W,5%, 0805
Resistor, 10kOhm,
0.125W, 5%, 0805
Resistor, 12.7kOhm,
0.125W, 5%, 0805
Resistor, 330kOhm,
0.5W, 5%, 1210
Resistor, 1KOhm,
0.125W, 5%, 0805
Resistor, 47Ohm,
0.125W, 5%, 0805
Resistor, 0.27Ohm,
1W, 1%, 2512
Resistor, 120kOhm,
0.25W, 5%, 1206
Resistor, 18KOhm,
0.25W, 5%, 0805
Resistor, NTC,
2.5Ohm
Test point, 0.063"D
Orange
Test point, 0.063"D
White
Test point, 0.063"D
Yellow
Test point, 0.063"D
Red
Test point, 0.063"D
Black
Test point, 0.063"D
Purple
Test point, 0.063"D
Blue
Header, 3 position,
0.156" vertical
Fuse,
3.15A/250VRadial
PCB
Standoff, HEX 0.65"L
4-40THR Nylon
Screw, Phillips 4-40 x
1/4
Heatsink, TO-220
www.irf.com
ERJ-14YJ334U
ERJ-6GEYJ102V
ERJ-6GEYJ470V
ERJ-1TRQJR27U
PanasonicECG
PanasonicECG
PanasonicECG
PanasonicECG
ERJ-8GEYJ124V
PanasonicECG
3
Rstart1,R
start2,RSt
art3
ERJ-6GEY183V
PanasonicECG
1
RZX
B57236S0259L002
Epcos
1
RNTC2
5008
Keystone
1
VCC
5007
Keystone
1
ZX
5009
Keystone
1
PFC
5005
Keystone
1
VOUT
5006
Keystone
2
COM,CO
M2
5124
Keystone
1
OC
5122
Keystone
1
VDC
26-60-4030
Molex
2
CON1,CO
N3
RST 3.15
Bel Fuse Inc
1
F1
IRPLPFC1 Rev A
1902F
1
Keystone
PMS 440 0025 PM
591202B00000G
AN-1179
B&F
Fastener
Aavid
Thermalloy
4
4
1
20
8. Test Results
The IRPLLED1 board was tested using the following test equipment:
Oscilloscope: LeCroy Wave Surfer 454
Power Analyser: Chroma 6630
AC Power Source: California Instruments 801P
Electronic Load: Chroma 6314 frame + 63105 module
Using an electronic AC power source ensures that the input voltage waveform
will be a nearly pure sine wave and this will give the most accurate possible
current THD and power factor measurements. Measurements made with
supplied connected through auto transformers and/or isolation transformers can
give slightly worse results as the voltage waveform applied to the IRPLPFC1
input is not a pure sinusoid.
Input frequency was 60Hz in all tests, load was 90W, output voltage was 425V.
Input Voltage (RMS)
90
100
110
120
130
140
150
160
170
180
190
200
210
220
230
240
250
260
270
Power Factor
0.995
0.995
0.995
0.994
0.993
0.992
0.991
0.989
0.988
0.986
0.980
0.976
0.973
0.970
0.966
0.962
0.957
0.952
0.947
THDi (%)
7.0
6.5
6.0
5.6
5.3
5.0
4.9
4.9
5.0
5.2
7.3
7.9
8.1
8.5
9.0
9.5
10.1
10.6
11.3
Table 1: 90W PF and THDi Results
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1
12
0.99
10
0.98
0.97
PF
0.95
6
0.94
THDi
8
0.96
PF
THDi
4
0.93
0.92
2
0.91
0
27
0
25
0
23
0
21
0
19
0
17
0
15
0
13
11
0
0
90
0.9
RMS Voltage
Figure 11: 90W PF and THDi vs input voltage at dull load
Figure 11 shows the results from table 1 in graphical form with 90W load as the
input voltage varies from 90 to 270Vrms. The THDi remains under 10% over
most of this range measuring 5.5% at 120Vrms and 8.4% at 220Vrms.
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Tests carried out at 120VAC input:
Input Power (W)
10.0
20.2
30.3
39.5
50.0
60.5
69.8
80.4
89.8
Power Factor
0.894
0.961
0.979
0.987
0.990
0.992
0.993
0.994
0.994
THDi (%)
22.2
13.0
8.7
6.1
5.1
5.0
5.2
5.5
5.5
Table 2: Power factor and THDi vs load at 120VAC
Figure 12 : VBUS, IAC and VDC at 120VAC, 90W
The green trace in Figure 12 shows the sinusoidal shape of the power factor
corrected current at 120VAC line input and 90W load. The 425V nominal DC bus
voltage is also in the brown trace along with the VDC pin input consisting of the
divided rectified bridge voltage used to determine the on time modulation which
minimizes cross over distortion as seen.
Table 2 shows the IRPLPFC1 reference design at low line the power factor
remains high and THDi remains under 10% down to below 30% of maximum
load.
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AN-1179
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Figure 13 : VBUS, Gate Drive and ZX at 120VAC, 90W, line peak
Figure 14 : VBUS, Gate Drive and ZX at 120VAC, 90W, line valley
Figures 13 and 14 show on time modulation functioning by displaying the red
MOSFET gate drive voltage and the ZX input voltage. Close to the AC input zero
crossing the on time is increased, shown in figure 14.
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Figure 15 : VBUS, Gate Drive and OC at 120VAC, 90W
Figure 16: VBUS and Gate Drive at startup, 120VAC, 10W
Figure 15 shows the OC input reaching a peak of close to 500mV at full load.
This increases when the line voltage is reduced but remains sufficiently below
the 1.1V OC threshold to prevent cycle by cycle current limiting occurring during
normal operation. It is important to correctly size the current sense resistor to
prevent current limiting under low line, high load conditions as this distorts the AC
line current, reduces the power factor and increases THDi.
Figure 16 shows the dynamic over voltage protection operating at startup at very
light load to prevent the voltage from overshooting. The gate drive shown in the
red trace is disabled when the bus voltage exceeds the nominal level. This is
necessary since the error amplifier control loop operates slowly over many cycles
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AN-1179
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and would be unable to prevent a significant overshoot from occurring. The
dynamic over voltage protection allows the board to be switched on with an open
circuit at the output without a significant overshoot occurring at the output.
Tests carried out at 220VAC input:
Input Power (W)
10.4
19.7
30.6
40.7
49.8
60.0
70.3
80.5
89.6
Power Factor
0.576
0.763
0.861
0.917
0.937
0.951
0.959
0.966
0.970
THDi (%)
24.5
17.4
22.0
15.0
13.1
11.7
10.7
9.3
8.4
Table 3: Power factor and THDi vs load at 220VAC
Figure 17 : VBUS, IAC and VDC at 220VAC, 90W
The green trace in Figure 17 shows the sinusoidal shape of the power factor
corrected current at 220VAC line input and 90W load. As expected the amplitude
of the current is reduced and the cross over distortion is higher than at 120VAC.
The 425V nominal DC bus voltage is also in the brown trace along with the VDC
pin input consisting of the divided rectified bridge voltage at a higher amplitude
than at 120VAC input.
Table 3 shows the IRPLPFC1 reference design at high line the power factor and
THDi are not as good as at 120VAC. This is inevitably the case in wide input
range designs. In order to optimize performance at 220VAC the circuit would not
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AN-1179
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be able to operate at 120VAC. This is because the inductor value would need to
be increased and input filter capacitors would need to be reduced.
Figure 18 : VBUS, Gate Drive and ZX at 220VAC, 90W, line peak
Figure 19 : VBUS, Gate Drive and ZX at 220VAC, 90W, line valley
Figures 18 and 19 show on time modulation functioning by displaying the red
MOSFET gate drive voltage and the ZX input voltage. Close to the AC input zero
crossing the on time is increased, shown in figure 19.
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Figure 20 : VBUS, Gate Drive and OC at 220VAC, 90W
Figure 21: VBUS and Gate Drive at startup, 220VAC, 10W
Figure 20 shows the OC input reaching a peak of close to 500mV at full load.
This increases when the line voltage is reduced but remains sufficiently below
the 1.1V OC threshold to prevent cycle by cycle current limiting occurring during
normal operation. Since the rectified line voltage is higher the slope of the current
is steeper resulting.
Figure 21 shows the dynamic over voltage protection operating at startup with a
very light load to prevent the voltage from overshooting. The gate drive shown in
the red trace is disabled when the bus voltage exceeds the nominal level. The
boards may be switched on into an open circuit at high line input without
experiencing a significant overshoot at the output.
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AN-1179
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Efficiency Measurements
The IRPLPFC1 efficiency was measured at 90W load at 120VAC and at 220VAC
inputs;
AC Line Voltage (rms)
Input Power (W)
DC Output Voltage (V)
DC Output Current (A)
Output Power (W)
Efficiency (%)
120
90.1
422.4
0.202
85.3
94.7
220
88.5
422.8
0.202
85.4
96.5
Table 4: Efficiency at 120VAC and 220VAC
Conducted EMI
Figure 22: Conducted EMI measurements
Figure 22 shows series mode quasi peak measurements of conducted EMI on
each of the AC input lines. The limit line is from CISPR 22 class B which also
applies to many other standards.
IR WORLD HEADQUARTERS: 101 N. Sepulveda Blvd., El Segundo, California 90245 Tel: (310) 252-7105
Data and specifications subject to change without notice. 05/01/2012
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AN-1179
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