TNY263PN Power Integrations, TNY263PN Datasheet

IC OFFLINE SWIT OTP OCP HV 8DIP

TNY263PN

Manufacturer Part Number
TNY263PN
Description
IC OFFLINE SWIT OTP OCP HV 8DIP
Manufacturer
Power Integrations
Series
TinySwitch®-IIr
Datasheet

Specifications of TNY263PN

Output Isolation
Isolated
Frequency Range
124 ~ 140kHz
Voltage - Output
700V
Power (watts)
7.5W
Operating Temperature
-40°C ~ 150°C
Package / Case
8-DIP (0.300", 7.62mm), 7 Leads
Output Voltage
5.8 V
Input / Supply Voltage (max)
265 VAC
Input / Supply Voltage (min)
85 VAC
Duty Cycle (max)
68 %
Switching Frequency
132 KHz
Supply Current
200 uA
Operating Temperature Range
- 40 C to + 150 C
Mounting Style
Through Hole
Lead Free Status / RoHS Status
Lead free / RoHS Compliant
Other names
596-1045-5
TNY263-268
TinySwitch-II Family
Enhanced, Energy Effi cient, Low Power
Off-line Switcher
Product Highlights
TinySwitch-II Features Reduce System Cost
Better Cost/Performance over RCC & Linears
EcoSmart
High Performance at Low Cost
Description
TinySwitch-II integrates a 700 V power MOSFET, oscillator, high
voltage switched current source, current limit and thermal
shutdown circuitry onto a monolithic device. The start-up and
operating power are derived directly from the voltage on the
DRAIN pin, eliminating the need for a bias winding and
associated circuitry. In addition, the TinySwitch-II devices
incorporate auto-restart, line undervoltage sense, and frequency
jittering. An innovative design minimizes audio frequency
components in the simple ON/OFF control scheme to practically
eliminate audible noise with standard taped/varnished
www.powerint.com
Fully integrated auto-restart for short circuit and open loop fault
protection – saves external component costs
Built-in circuitry practically eliminates audible noise with ordinary
dip-varnished transformer
Programmable line undervoltage detect feature prevents power
on/off glitches – saves external components
Frequency jittering dramatically reduces EMI (~10 dB)
– minimizes EMI fi lter component costs
132 kHz operation reduces transformer size – allows use of
EF12.6 or EE13 cores for low cost and small size
Very tight tolerances and negligible temperature variation on key
parameters eases design and lowers cost
Lowest component count switcher solution
Expanded scalable device family for low system cost
Lower system cost than RCC, discrete PWM and other
integrated/hybrid solutions
Cost effective replacement for bulky regulated linears
Simple ON/OFF control – no loop compensation needed
No bias winding – simpler, lower cost transformer
Simple design practically eliminates rework in manufacturing
No load consumption <50 mW with bias winding and
<250 mW without bias winding at 265 VAC input
Meets California Energy Commission (CEC), Energy Star, and
EU requirements
Ideal for cell-phone charger and PC standby applications
High voltage powered – ideal for charger applications
High bandwidth provides fast turn on with no overshoot
Current limit operation rejects line frequency ripple
Built-in current limit and thermal protection improves safety
®
– Extremely Energy Effi cient
®
Output Power Table
transformer construction. The fully integrated auto-restart circuit
safely limits output power during fault conditions such as output
short circuit or open loop, reducing component count and
secondary feedback circuitry cost. An optional line sense resistor
externally programs a line undervoltage threshold, which
eliminates power down glitches caused by the slow discharge of
input storage capacitors present in applications such as standby
supplies. The operating frequency of 132 kHz is jittered to
signifi cantly reduce both the quasi-peak and average EMI,
minimizing fi ltering cost.
Table 1.
Notes:
1. Minimum continuous power in a typical non-ventilated enclosed adapter
2. Minimum practical continuous power in an open frame design with adequate
3. Packages: P: DIP-8B, G: SMD-8B. Please see Part Ordering Information.
Figure 1.
TNY263 P/G
TNY264 P/G
TNY265 P/G
TNY266 P/G
TNY267 P/G
TNY268 P/G
measured at 50 °C ambient.
heat sinking, measured at 50 °C ambient (See Key Applications
Considerations).
HV DC Input
Wide-Range
+
Product
-
Output Power Table.
Typical Standby Application.
TinySwitch-II
3
Adapter
5.5 W
8.5 W
10 W
13 W
16 W
5 W
UV Resistor
230 VAC ± 15%
Optional
D
S
EN/UV
BP
1
Frame
7.5 W
Open
11 W
15 W
19 W
23 W
9 W
2
Adapter
3.7 W
5.5 W
10 W
4 W
6 W
8 W
85-265 VAC
1
PI-2684-021809
February 2009
Output
Frame
DC
4.7 W
7.5 W
9.5 W
Open
12 W
15 W
6 W
+
-
2

Related parts for TNY263PN

TNY263PN Summary of contents

Page 1

TNY263-268 ® TinySwitch-II Family Enhanced, Energy Effi cient, Low Power Off-line Switcher Product Highlights TinySwitch-II Features Reduce System Cost Fully integrated auto-restart for short circuit and open loop fault • protection – saves external component costs Built-in circuitry practically eliminates ...

Page 2

TNY263-268 BYPASS (BP) LINE UNDER-VOLTAGE 240 6.3 V ENABLE 1 OSCILLATOR ENABLE/ 1.0 V UNDER- VOLTAGE (EN/UV) Figure 2. Functional Block Diagram. Pin Functional Description DRAIN (D) Pin: Power MOSFET drain connection. Provides ...

Page 3

TinySwitch-II Functional Description TinySwitch-II combines a high voltage power MOSFET switch with a power supply controller in one device. Unlike conventional PWM (pulse width modulator) controllers, TinySwitch-II uses a simple ON/OFF control to regulate the output voltage. The TinySwitch-II controller ...

Page 4

TNY263-268 that cycle. The current limit state machine reduces the current limit threshold by discrete amounts under medium and light loads. The leading edge blanking circuit inhibits the current limit comparator for a short time (t ) after the power ...

Page 5

At high loads, when the EN/UV pin is high (less than 240 μA out of the pin), a switching cycle with the full current limit occurs. At lighter loads, when EN/UV is high, a switching cycle ...

Page 6

TNY263-268 V EN CLOCK D MAX I DRAIN V DRAIN Figure 9. TinySwitch-II Operation at Very Light Load. two main benefi ts. First, for a nominal application, this eliminates the cost of a bias winding and associated components. Secondly, for ...

Page 7

D1 1N4005 D2 1N4005 C1 3.3 μF 85-265 400 V VAC RF1 8.2 Ω Fusible R1 1.2 kΩ 1N4005 1N4005 L1 2.2 mH Figure 14. 2.5 W Constant Voltage, Constant Current Battery Charger with Universal Input (85-265 VAC). ...

Page 8

TNY263-268 A simple constant current circuit is implemented using the V of transistor Q1 to sense the voltage across the current sense resistor R4. When the drop across R4 exceeds the V transistor Q1, it turns on and takes over ...

Page 9

PERFORMANCE SUMMARY Continuous Output Power: 10.24 W ≥ 75% Efficiency: 140 - 375 VDC Input C1 0.01 μ TinySwitch-II U1 TNY266P +12 VDC μ Figure 15 ...

Page 10

TNY263-268 Key Application Considerations TinySwitch-II vs. TinySwitch Table 2 compares the features and performance differences between the TNY254 device of the TinySwitch-II family with the TinySwitch-II family of devices. Many of the new features eliminate the need for or reduce ...

Page 11

... In addition, the common/ return output connection should be taken directly from the secondary winding pin and not from the Y-capacitor connection point. PC Board Cleaning Power Integrations does not recommend the use of “no clean” fl ux. For the most up-to-date information visit the PI website at: www.powerint.com. 11 ...

Page 12

TNY263-268 Input Filter Capacitor + HV – TOP VIEW C BP Figure 17. Recommended Circuit Board Layout for TinySwitch-II with Undervoltage Lock Out Resistor. 12 Rev. H 02/09 Safety Spacing Y1- Capacitor PRI ...

Page 13

Absolute Maximum Ratings (1,4) DRAIN Voltage .................................. ................ -0 700 V DRAIN Peak Current: TNY263......................................400 mA TNY264.....................................400 mA .................................... TNY265......................................440 mA TNY266.....................................560 mA .................................... TNY267.....................................720 mA TNY268.....................................880 mA EN/UV Voltage ....................................................... -0 EN/UV Current ...

Page 14

TNY263-268 Parameter Symbol Control Functions (cont.) BYPASS Pin V Voltage BP BYPASS Pin V Voltage Hysteresis BPH EN/UV Pin Line Under- I Voltage Threshold LUV Circuit Protection Current Limit I LIMIT Initial Current Limit I INIT Leading Edge t Blanking ...

Page 15

Parameter Symbol Output (cont.) ON-State R Resistance DS(ON) OFF-State Drain I Leakage Current DSS Breakdown BV Voltage DSS Rise Time t R Fall Time t F Drain Supply Voltage Output EN/UV Delay t EN/UV Output Disable t Setup Time DST ...

Page 16

TNY263-268 D EN/ NOTE: This test circuit is not applicable for current limit or output characteristic measurements. Figure 18. TinySwitch-II General Test Circuit. Figure 19. TinySwitch-II Duty Cycle Measurement. 16 Rev. H 02/09 470 Ω ...

Page 17

Typical Performance Characteristics 1.1 1.0 0.9 -50 - 100 125 150 Junction Temperature (°C) Figure 22. Breakdown vs. Temperature. 1.2 1 TNY263/268 0.8 TNY264-266 TNY267 0.6 0.4 0 Temperature ( C) Figure ...

Page 18

TNY263-268 Typical Performance Characteristics (cont.) 1000 100 Scaling Factors: TNY263 TNY264 TNY265 TNY266 10 TNY267 TNY268 1 0 100 200 300 Drain Voltage (V) Figure 28. C vs. Drain Voltage. OSS 18 Rev. H 02/ 1.0 20 ...

Page 19

D S .004 (.10) -E- .240 (6.10) .260 (6.60) Pin 1 .367 (9.32) -D- .387 (9.83) .125 (3.18) .145 (3.68) -T- SEATING PLANE .100 (2.54) BSC .014 (.36) ⊕ .010 (.25) M .022 (.56) www.powerint.com ...

Page 20

TNY263-268 ⊕ .004 (.10) -E- .240 (6.10) .260 (6.60) Pin 1 .100 (2.54) (BSC) .367 (9.32) -D- .387 (9.83) .125 (3.18) .145 (3.68) .032 (.81) .048 (1.22) .037 (.94) .053 (1.35) Part Ordering Information TNY 264 G N ...

Page 21

Revision Notes A – B Corrected fi rst page spacing and sentence in description describing innovative design. Corrected Frequency Jitter in Figure 4 and Frequency Jitter in Parameter Table. Added last sentence to Over Temperature Protection section. Clarifi ed detecting ...

Page 22

... The products and applications illustrated herein (including transformer construction and circuits external to the products) may be covered by one or more U.S. and foreign patents, or potentially by pending U.S. and foreign patent applications assigned to Power Integrations. A complete list of Power Integrations patents may be found at www.powerint.com. Power Integrations grants its customers a license under certain patent rights as set forth at http://www ...

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