LNK500PN Power Integrations, LNK500PN Datasheet - Page 9

IC SWIT OCP CV/CC HV 8DIP

LNK500PN

Manufacturer Part Number
LNK500PN
Description
IC SWIT OCP CV/CC HV 8DIP
Manufacturer
Power Integrations
Series
LinkSwitch®r
Datasheet

Specifications of LNK500PN

Output Isolation
Isolated
Frequency Range
24 ~ 49.5kHz
Voltage - Output
700V
Power (watts)
4W
Operating Temperature
-40°C ~ 150°C
Package / Case
8-DIP (0.300", 7.62mm), 7 Leads
Output Voltage
5.6 V
Input / Supply Voltage (max)
265 VAC
Input / Supply Voltage (min)
85 VAC
Duty Cycle (max)
80 %
Switching Frequency
42 KHz
Supply Current
1.06 mA
Operating Temperature Range
- 40 C to + 150 C
Mounting Style
Through Hole
For Use With
596-1001 - KIT DESIGN ACCELERATOR ADAPTER
Lead Free Status / RoHS Status
Lead free / RoHS Compliant
Other names
596-1029-5

Available stocks

Company
Part Number
Manufacturer
Quantity
Price
Part Number:
LNK500PN
Manufacturer:
POWER
Quantity:
20 000
voltage and ±25% for current limit for overall variation in high
volume manufacturing. This includes device and transformer
tolerances and line variation. Lower power designs may have
poorer constant current linearity.
As the output load reduces from the peak power point, the
output voltage will tend to rise due to tracking errors compared
to the load terminals. Sources of these errors include the
output cable drop, output diode forward voltage and leakage
inductance, which is the dominant cause. As the load reduces,
the primary operating peak current reduces, together with the
leakage inductance energy, which reduces the peak charging
of the clamp capacitor. With a primary leakage inductance of
50 µH, the output voltage typically rises 30% over a 100% to
5% load change.
At very light or no-load, typically less than 2 mA of output current,
the output voltage rises due to leakage inductance peak charging
of the secondary. This voltage rise can be reduced with a small
preload with little change to no-load power consumption.
The output voltage load variation can be improved across the
whole load range by adding an optocoupler and secondary
reference (Figure 6). The secondary reference is designed to only
provide feedback above the normal peak power point voltage
to maintain the correct constant current characteristic.
Component Selection
The schematic shown in Figure 5 outlines the key components
needed for a LinkSwitch supply.
Clamp diode – D1
Diode D1 should be either a fast (t
type (t
recovery types are preferred, being typically lower cost. Slow
diodes are not recommended; they can allow excessive DRAIN
ringing and the LinkSwitch to be reverse biased.
Clamp Capacitor – C2
Capacitor C2 should be a 0.1 µF, 100 V capacitor. Low cost
metallized plastic film types are recommended. The tolerance
of this part has a very minor effect on the output characteristic
so any of the standard ±5%, ±10% or ±20% tolerances are
acceptable. Ceramic capacitors are not recommended. The
common dielectrics used such as Y5U or Z5U are not stable
with voltage or temperature and may cause output instability.
Ceramic capacitors with high stability dielectrics may be used
but are expensive compared to metallized film types.
CONTROL Pin Capacitor – C1
Capacitor C1 is used during start-up to power LinkSwitch and
sets the auto-restart frequency. For designs that have a battery
load, this component should have a value of 0.22 µF and for
resistive loads, a value of 1 µF. This ensures there is sufficient
rr
<50 ns), with a voltage rating of 600 V or higher. Fast
r r
<250 ns) or ultra-fast
time during start-up for the output voltage to reach regulation.
Any capacitor type is acceptable with a voltage rating of
10 V or above.
Feedback Resistor – R1
The value of R1 is selected to give a feedback current into the
CONTROL pin of approximately 2.3 mA at the peak output
power point of the supply. The actual value depends on the V
selected during design. Any 0.25 W resistor is suitable.
Output Diode – D2
Either PN fast, PN ultra-fast or Schottky diodes can be used,
depending on the efficiency target for the supply, Schottky
diodes giving higher efficiency then PN diodes. The diode
voltage rating should be sufficient to withstand the output
voltage plus the input voltage transformed through the turns
ratio (a typical V
Slow recovery diodes are not recommended (1N400X types).
Output Capacitor – C4
Capacitor C4 should be selected such that its voltage and ripple
current specifications are not exceeded.
LinkSwitch Layout considerations
Primary Side Connections
Since the SOURCE pins in a LinkSwitch supply are switching
nodes, the copper area connected to SOURCE together with C1,
C2 and R1 (Figure 5) should be minimized, within the thermal
contraints of the design, to reduce EMI coupling.
The CONTROL pin capacitor C1 should be located as close as
possible to the SOURCE and CONTROL pins.
To minimize EMI coupling from the switching nodes on the
primary to both the secondary and AC input, the LinkSwitch
should be positioned away from the secondary of the transformer
and AC input.
Routing the primary return trace from the transformer primary
around LinkSwitch and associated components further reduces
coupling.
Y capacitor
If a Y capacitor is required, it should be connected close to the
transformer secondary output return pin(s) and the primary bulk
capacitor negative return. Such placement will maximize the
EMI benefit of the Y capacitor and avoid problems in common-
mode surge testing.
OR
of 50 V requires a diode PIV of 50 V).
LNK500
2/05
D
9
OR

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