PDF TNY380 Data sheet ( Hoja de datos )

Número de pieza	TNY380
Descripción	Off-Line Switcher
Fabricantes	Power Integrations
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TNY375-380 TinySwitch®-PK Family Energy-Efficient, Off-Line Switcher With Enhanced Peak Power Performance Product Highlights Lowest System Cost with Enhanced Flexibility • Simple ON/OFF control, no loop compensation needed • Unique Peak Mode feature extends power range without increasing transformer size • Maximum frequency and current limit boosted at peak loads • Selectable current limit through BP/M capacitor value • Higher current limit extends maximum power in open frame • Lower current limit improves efficiency in enclosed adapters • Allows optimum TinySwitch-PK choice by swapping devices with no other circuit redesign • Tight I2f parameter tolerance reduces system cost • Maximizes MOSFET and magnetics power delivery • ON time extension – typically extends low line regulation range/ hold-up time to reduce input bulk capacitance • Self-biased: no bias winding required for TNY375-376; winding required for TNY377-380 • Frequency jittering reduces EMI filter costs • Optimized pin out eases pcb/external heatsinking • Quiet source-connected heatsink pins for low EMI Enhanced Safety and Reliability Features • Accurate hysteretic thermal shutdown with automatic recovery provides complete system level overload protection and eliminates need for manual reset • Auto-restart delivers <3% maximum power in short circuit and open loop fault conditions • Output overvoltage shutdown with optional Zener • Line undervoltage detect threshold set using a single resistor • Very low component count enhances reliability and enables single sided printed circuit board layout • High bandwidth provides fast turn on with no overshoot and excellent transient load response • Extended creepage between DRAIN and all other pins improves field reliability EcoSmart®– Extremely Energy Efficient • Easily meets all global energy efficiency regulations • No-load <170 mW at 265 VAC without bias winding, <60 mW with bias winding • ON/OFF control provides constant efficiency down to very light loads – ideal for mandatory CEC efficiency regulations and 1 W PC standby requirements Applications • Applications with high peak-to-continuous power demands – DVDs, PVRs, active speakers (e.g. PC audio), audio amplifiers, modems, photo printers • Applications with high power demands at startup (large output capacitance or motor loads) - PC standby, low voltage motor drives AC + IN DC OUT D TinySwitch-PK S EN/UV BP/M Figure 1. Typical Peak Power Application. PI-4266-010906 Output Power Table Product3 230 VAC ± 15% Adapter1 Open Frame2 Peak 85-265 VAC Adapter1 Open Frame2 Peak TNY375PN TNY376PN TNY377PN TNY378PN TNY379PN 8.5 W 10 W 13 W 16 W 18 W 15 W 19 W 23.5 W 28 W 32 W 16.5 W 22 W 28 W 34 W 39 W 6W 7W 8W 10 W 12 W 11.5 W 15 W 18 W 21.5 W 25 W 12.5 W 17 W 23 W 27 W 31 W TNY380PN 20 W 36.5 W 45 W 14 W 28.5 W 35 W Table 1. Output Power Table. Notes: 1. Minimum continuous power in a typical non-ventilated enclosed adapter measured at +50 °C ambient. Use of an external heatsink will increase power capability. 2. Minimum continuous power in an open frame design (see Key Applications Considerations). 3. Packages: P: DIP-8C. Lead free only. See Part Ordering Information. Description TinySwitch-PK incorporates a 700 V MOSFET, oscillator, high- voltage switched current source, current limit (user selectable), and thermal shutdown circuitry. A unique peak mode feature boosts current limit and frequency for peak load conditions. The boosted current limit provides the peak output power while the increased peak mode frequency ensures the transformer can be sized for continuous load conditions rather than peak power demands. www.powerint.com May 2007 www.DataSheet.in 1 page TNY375-380 VEN CLOCK DCMAX IDRAIN VDRAIN PI-2749-082305 Figure 6. Operation at Near Maximum Loading (fOSC 264 kHz). VEN CLOCK DCMAX The EN/UV pin signal is generated on the secondary by comparing the power supply output voltage with a reference voltage. The EN/UV pin signal is high when the power supply output voltage is less than the reference voltage. In a typical implementation, the EN/UV pin is driven by an optocoupler. The collector of the optocoupler transistor is connected to the EN/UV pin, and the emitter is connected to the SOURCE pin. The optocoupler LED is connected in series with a Zener diode across the DC output voltage to be regulated. When the output voltage exceeds the target regulation voltage level (optocoupler LED voltage drop plus Zener voltage), the optocoupler LED will start to conduct, pulling the EN/UV pin low. The Zener diode can be replaced by a TL431 reference circuit for improved accuracy. ON/OFF Operation with Current Limit State Machine The internal clock of the TinySwitch-PK runs at all times. At the beginning of each clock cycle, it samples the EN/UV pin to decide whether or not to implement a switch cycle, and based on the sequence of samples over multiple cycles, it determines the appropriate current limit. At high loads, the state machine sets the current limit to its highest value. With TinySwitch-PK, when the state machine sets the current limit to its highest value, the oscillator frequency is also doubled, providing the unique peak mode operation. At lighter loads, the state machine sets the current limit to reduced values. At these lower current limit levels, the oscillator frequency returns to the standard value. At near maximum load, TinySwitch-PK will conduct during nearly all of its clock cycles (Figure 6). At slightly lower load, it will “skip” additional cycles in order to maintain voltage regulation at the power supply output (Figure 7). At medium loads, more cycles will be skipped, the current limit will be IDRAIN VDRAIN VEN CLOCK DCMAX PI-2667-082305 Figure 7. Operation at Moderately Heavy Loading (fOSC 264 kHz). Enable Function TinySwitch-PK senses the EN/UV pin to determine whether or not to proceed with the next switching cycle. The sequence of cycles is used to determine the current limit. Once a cycle is started, it always completes the cycle (even when the EN/UV pin changes state halfway through the cycle). This operation results in a power supply in which the output voltage ripple is determined by the output capacitor, amount of energy per switch cycle, and the delay of the feedback. IDRAIN VDRAIN Figure 8. Operation at Medium Loading (fOSC 132 kHz). PI-4540-050407 www.powerint.com www.DataSheet.in Rev. A 05/07 5 Page TNY375-380 Copper area for heat sinking + HV - TOP VIEW Return bias winding directly to input capacitor Safety Spacing CapYa1c-itor Input Filter Capacitor D S S EN/UV S PRI BIAS PRI BIAS T r a n s f o r m e r SEC Maximize hatched copper areas ( ) for optimum heatsinking Output Rectifier S BP CBP RUV Bypass capacitor connection to device should be short Figure 16. Layout Considerations for TinySwitch-PK Using P Package. Opto- coupler Route connections to EN/UV pin (including undervoltage resistor) away from drain connected traces - DC + OUT PI-4675-051507 Y-Capacitor The placement of the Y-capacitor should be directly from the primary input filter capacitor positive terminal to the common/ return terminal of the transformer secondary. Such a placement will route high magnitude common mode surge currents away from the TinySwitch-PK device. Note – if an input π (C, L, C) EMI filter is used, then the inductor in the filter should be placed between the negative terminals on the input filter capacitors. Optocoupler Place the optocoupler physically close to the TinySwitch-PK device to minimize the primary side trace lengths. Keep the high current, high voltage drain and clamp traces away from the optocoupler to prevent noise pick up. Output Diode For best performance, the area of the loop connecting the secondary winding, the Output Diode, and the Output Filter Capacitor should be minimized. In addition, for axial diodes, sufficient copper area should be provided at the anode and cathode terminal of diode for heatsinking. A larger area is preferred at the quiet cathode terminal. A large anode area can increase high frequency radiated EMI. Quick Design Checklist As with any power supply design, all TinySwitch-PK designs should be verified on the bench to make sure that component specifications are not exceeded under worst case conditions. The following minimum set of tests is strongly recommended: 1. M65a0xiVmautmhidgrhaeinstvionlptaugtevo–ltVaegreifyanthdepVeDaSkd(ooevsernlooatde)xocuetepdut power. The 50 V margin to the 700 V BVDSS specification gives margin for design variation. 2. Maximum drain current – At maximum ambient temperature, maximum input voltage, and peak output (overload) power, verify drain current waveforms for any signs of transformer saturation and excessive leading edge current spikes at startup. Repeat under steady state conditions and verify that tochufertrhleeenattdLsEinBh(gMoinue).lddgUbenedcbeuerrrlaoelnwl tctoshpnediksietpioeenvcseifnitehtdeisambbaesxlooimlwutueImINmIT daatrxatimihneumend ratings. 3. Thermal Check – At specified maximum output power, minimum input voltage, and maximum ambient temperature, verify that the temperature specifications are not exceeded for TinySwitch-PK device, transformer, output diode, and output capacitors. Enough thermal margin should be allowed for part-to-part variation of the RDS(ON) of TinySwitch-PK device as specified in the data sheet. Under low-line maximum power, a maximum TinySwitch-PK device SOURCE pin temperature of 110 °C is recommended to allow for these variations. Design Tools Up-to-date information on design tools can be found at the Power Integrations web site: www.powerint.com. www.powerint.com www.DataSheet.in 11 Rev. A 05/07 11 Page

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