TNY375 데이터 시트보기 (PDF) - Power Integrations, Inc
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TNY375
Power Integrations, Inc
TNY375 Datasheet PDF : 20 Pages
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TNY375-380
D1
FR106
F1
L
3.15 A
85-265
VAC
N
D3
1N4007
D2
FR106
C1
22 MF
400 V
D4
1N4007
L1
5 mH
VR1
P6KE180A
C2
22 MF
400 V
R2
47 7
D5
FR106
TinySwitch-PK
U1
TNY376P
D
EN/UV
BP
S C4
10 MF
50 V
C5
330 pF
250 VAC
R1
100 7
C3
10 nF
1 kV
U2B
LTV817A
JP1
T1
EEL19
6
N.C.
11
1
7
4
3
8,9,10
5
12
D6
UF4003
D7
1N5819
D8
SB340
C9
1000 MF
10 V
C11
47 MF
25 V
L2
3.3 MH
L3
3.3 MH
R6
20 k7
1%
L4
3.3 MH
C7
1000 MF
25 V
C5
220 MF
25 V
JP2
R4
200 7
1/2 W
C6
100 MF
25 V
C12
220 MF
25 V
D9
UF4003
R3
17
1/2 W
R5
1 k7
U2A
LTV817A
C14
100 nF
50 V
C8
470 MF
10 V
R7
6.34 k7
1%
+12 V, 0.64 A
+5.0 V, 0.6 A
+3.3 V, 0.6 A
C10
470 MF
10 V
RTN
-12 V, 0.03 A
Figure 14. TNY376P, Four Output, 7.5 W, 13 W Peak Universal Input Power Supply.
C13
10 MF
50 V
U3
L431
2%
R9
3.3 k7
R8
10 k7
1%
PI-4673-051107
Applications Examples
The circuit shown in Figure 14 is a low cost universal AC input,
four-output flyback power supply utilizing a TNY376. The
continuous output power is 7.5 W with a peak of 13 W. The
output voltages are 3.3 V, 5 V, 12 V, and –12 V.
The rectified and filtered input voltage is applied to the primary
winding of T1. The other side of the transformer’s primary is
driven by the integrated MOSFET in U1. Diode D5, C3, R1, R2,
and VR1 compose the clamp circuit, limiting the leakage
inductance turn-off voltage spike on the DRAIN pin to a safe
value. The use of a combination Zener clamp and parallel RC
optimizes both EMI and energy efficiency.
Both the 3.3 V and 5 V outputs are sensed through resistors R6
and R7. The voltage across R8 is regulated to 2.5 V by reference
IC U3. If the voltage across R8 begins to exceed 2.5 V, then
current will flow in the LED inside the optocoupler U2, driven by
the cathode of U3. This will cause the transistor of the
optocoupler to sink current from the EN/UV pin of U1. When the
current exceeds the ENABLE pin threshold current, the next
switching cycle is inhibited. Conversely, when the voltage across
resistor R8 falls below 2.5 V, and the current out of the ENABLE
pin is below the threshold, a conduction cycle is allowed to
occur. By adjusting the number of enabled cycles, regulation is
maintained. As the load reduces, the number of enabled cycles
decreases, lowering the effective switching frequency and
scaling switching losses with load. This provides almost
constant efficiency down to very light loads, ideal for meeting
energy efficiency requirements.
The input filter circuit (C1, L1 and C2) reduces conducted EMI.
To improve common mode EMI, this design makes use of
E-ShieldTM shielding techniques in the transformer, reducing
common mode displacement currents, and reducing EMI. These
techniques, combined with the frequency jitter of TNY376, give
excellent EMI performance, with this design achieving >10 dBmV
of margin to EN55022 Class B conducted EMI limits.
For design flexibility, the value of C4 can be selected to pick one
of the three current limit options in U4. Doing so allows the
designer to select the current limit appropriate for the application.
• Standard current limit is selected with a 0.1 mF BP/M pin
capacitor and is the normal choice for typical applications.
• When a 1 mF BP/M pin capacitor is used, the current limit is
reduced, offering reduced RMS device currents and therefore
improved efficiency, but at the expense of maximum power
capability. This is ideal for thermally challenging designs where
dissipation must be minimized.
• When a 10 mF BP/M pin capacitor is used, the current limit is
increased, extending the power capability for applications
requiring higher peak power or continuous power where the
thermal conditions allow.
Further flexibility comes from the current limits between adjacent
TinySwitch-PK family members being compatible. The reduced
current limit of a given device is equal to the standard current
limit of the next smaller device, and the increased current limit is
equal to the standard current limit of the next larger device.
Rev. A 05/07
www.powerint.com
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