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1 ACDC_LinkSwitch-HP_050415; Rev.2.1; Copyright Power Integrations 2015 INPUT INFO OUTPUT UNIT2 ENTER APPLICATION VARIABLES3 VACMIN 90 90 V4 VACMAX 265 265 V5 fL 50 50 Hz6 VO 5 5 V7 PO 17 17 W8 n 0,82 0,829 Z 0,5010 VB 10 V11 tC 3 ms12 CIN 56 56 uF13 Package K K14 Enclosure Adapter Adapter15 Heatsink PCB-R PCB-R161718 ENTER LinkSwitch-HP VARIABLES19 LinkSwitch-HP Auto LNK6765K20 ILIMITMIN 1,209 A21 ILIMITMAX 1,391 A22 ILIMITMIN_EXT 0,725 A23 ILIMITMAX_EXT 0,835 A24 KI 0,6 0,60025 Rpd 23,20 k-ohm26 Cpd 10,00 10,00 nF27 Total programmed delay 0,06 sec28 fS 132 kHz29 fSmin 120 kHz30 fSmax 136 kHz31 KP 0,50 0,5032 VOR 110,00 110,00 V33 Voltage Sense34 VUVON 100,00 100,00 V35 VUVOFF 40,70 V36 VOV 452,30 V37 FMAX_FULL_LOAD 129,79 kHz38 FMIN_FULL_LOAD 114,52 kHz39 TSAMPLE_FULL_LOAD 3,17 us40 TSAMPLE_LIGHT_LOAD 2,21 us41 VDS 1,50 V42 VD 0,50 V43 VDB 0,70 V44454647 FEEDBACK SENSING SECTION48 RFB1 39,20 k-ohms49 RFB2 8,66 k-ohms505152 ENTER TRANSFORMER CORE/CONSTRUCTION VARIABLES53 Select Core Size EFD25 EFD2554 Core EFD2555 Custom Core56 AE 0,58 cm^257 LE 5,70 cm58 AL 1800 nH/T^259 BW 16,4 mm60 M 3,50 3,50 mm61 L 362 NS 4636465 DC INPUT VOLTAGE PARAMETERS66 VMIN 85 85 V67 VMAX 375 375 V686970 CURRENT WAVEFORM SHAPE PARAMETERS71 DMAX 0,5772 IAVG 0,24 A73 IP 0,57 A74 IR 0,29 A75 IRMS 0,33 A767778 TRANSFORMER PRIMARY DESIGN PARAMETERS79 LP_TYP 1443 uH80 LP_TOL 7 7 %
163 Total power 16,2 W164165 Negative Output N/A N/A166
Transformer Construction ParametersVar Value Units DescriptionCore Type EFD25 Core TypeCore Material PC95 Core MaterialBobbin Reference Generic, 5 pri. + 5 sec. Bobbin ReferenceBobbin Orientation Horizontal Bobbin typePrimary Pins 5 Number of Primary pins usedSecondary Pins 5 Number of Secondary pins used (Manual Overwrite)LP 1443 µH Nominal Primary InductanceML 3,50 mm Safety Margin on Left WidthMR 3,50 mm Safety Margin on Right WidthLG 0,283 mm Estimated Gap Length
Feedback WindingVar Value Units DescriptionNFB 8 Feedback Winding Number of TurnsWire Size 31 AWG Wire size of Feedback windingsWinding Type Quadfilar (x4) Wire type of Feedback windingsLayers 0,91 Feedback Winding LayersStart Pin(s) 2 Starting pin(s) for Feedback winding (Manual Overwrite)Termination Pin(s) 1 Termination pin(s) for Feedback winding (Manual Overwrite)
Primary Winding Section 1Var Value Units DescriptionNP1 40 Number of Primary Winding Turns in the First Section of PrimaryWire Size 26 AWG Primary Winding - Wire SizeWinding Type Single (x1) Primary Winding - Number of Parallel Wire StrandsL 1,92 Primary Winding - Number of LayersStart Pin(s) 4 Starting pin(s) for first section of primary winding (Manual Overwrite)Termination Pin(s) 3 Termination pin(s) for first section of primary winding (Manual Overwrite)
Primary Winding Section 2Var Value Units DescriptionNP2 40 Rounded (Integer) Number of Primary winding turns in the second section of primaryWire Size 26 AWG Primary Winding - Wire SizeWinding Type Single (x1) Primary Winding - Number of Parallel Wire StrandsL2 1,92 Primary Number of Layers in 2nd split windingStart Pin(s) 3 Starting pin(s) for the second section of primary winding (Manual Overwrite)Termination Pin(s) 5 Termination pin(s) for the second section of primary winding (Manual Overwrite)
Output 1Var Value Units DescriptionVO 5,00 V Typical Output VoltageIO 1,00 A Output CurrentVOUT_ACTUAL 5,00 V Actual Output VoltageNS 4 Secondary Number of TurnsWire Size 24 AWG Wire size of secondary winding (Manual Overwrite)Winding Type 6-Filar (x6) Output winding number of parallel strands (Manual Overwrite)L_S_OUT 1,45 Secondary Output Winding LayersStart Pin(s) 6,7 Starting pin(s) for Output winding (Manual Overwrite)Termination Pin(s) 8,9 Termination pin(s) for Output winding (Manual Overwrite)
Output 2Var Value Units DescriptionVO 16,00 V Typical Output VoltageIO 0,70 A Output CurrentVOUT_ACTUAL 15,80 V Actual Output VoltageNS 8 Secondary Number of TurnsWire Size 25 AWG Wire size of secondary winding (Manual Overwrite)Winding Type Quadfilar (x4) Output winding number of parallel strands (Manual Overwrite)L_S_OUT 1,72 Secondary Output Winding LayersStart Pin(s) 10 Starting pin(s) for Output winding (Manual Overwrite)Termination Pin(s) 6 Termination pin(s) for Output winding (Manual Overwrite)
Electrical Diagram
Mechanical Diagram
Winding InstructionUse 3,50 mm margin (item [3]) on the left side. Use 3,50 mm margin (item [3]) on the right side.
Primary Winding (Section 1)Start on pin(s) 4 using item [6] at the start leads and wind 40 turns (x 1 filar) of item [8]. in 2 layer(s) from left to right. Winding direction is clockwise. Add 1 layer of tape, item [5], in between each primary winding layer. At the end of 1stlayer, continue to wind the next layer from right to left. On the final layer, spread the winding evenly across entire bobbin. Finish this winding on pin(s) 3 using item [6] at the finish leads.Add 3 layers of tape, item [4], for insulation.
Secondary WindingStart on pin(s) 6,7 using item [6] at the start leads and wind 4 turns (x 6 filar) of item [9]. Spread the winding evenly across entire bobbin. Winding direction is clockwise. Finish this winding on pin(s) 8,9 using item [6] at the finish leads.Add 1 layer of tape, item [4], for insulation.Start on pin(s) 10 using item [6] at the start leads and wind 8 turns (x 4 filar) of item [10]. Spread the winding evenly across entire bobbin. Winding direction is clockwise. Finish this winding on pin(s) 6 using item [6] at the finish leads.Add 3 layers of tape, item [4], for insulation.
Feedback WindingStart on any (temp) pin on the secondary side and wind 8 turns (x 4 filar) of item [11]. Winding direction is clockwise. Spread the winding evenly across entire bobbin. Finish this winding on pin(s) 1 using item [6] at the finish leads. Moveend of wire from temp pin and terminate it on pin 2.Add 2 layers of tape, item [4], for insulation.
Primary Winding (Section 2)Start on pin(s) 3 using item [6] at the start leads and wind 40 turns (x 1 filar) of item [8]. in 2 layer(s) from left to right. Winding direction is clockwise. Add 1 layer of tape, item [5], in between each primary winding layer. At the end of 1stlayer, continue to wind the next layer from right to left. On the final layer, spread the winding evenly across entire bobbin. Finish this winding on pin(s) 5 using item [6] at the finish leads.Add 3 layers of tape, item [4], for insulation.
Core AssemblyAssemble and secure core halves. Item [1].
VarnishDip varnish uniformly in item [7]. Do not vacuum impregnate.
Comments1. Pins 6 and 7 are electrically shorted to each other on the PCB via a copper trace.
2. Pins 8 and 9 are electrically shorted to each other on the PCB via a copper trace.3. Use of a grounded flux-band around the core may improve the EMI performance.
MaterialsItem Description[1] Core: EFD25, PC95, gapped for ALG of 226 nH/T²[2] Bobbin: Generic, 5 pri. + 5 sec.[3] Tape: Polyester web 3,50 mm wide[4] Barrier Tape: Polyester film [1 mil (25 µm) base thickness], 16,40 mm wide[5] Separation Tape: Polyester film [1 mil (25 µm) base thickness], 9,40 mm wide[6] Teflon Tubing # 22[7] Varnish[8] Magnet Wire: 26 AWG, Solderable Double Coated[9] Magnet Wire: 24 AWG, Solderable Double Coated[10] Magnet Wire: 25 AWG, Solderable Double Coated[11] Magnet Wire: 31 AWG, Solderable Double Coated
Electrical Test SpecificationsParameter Condition SpecElectrical Strength, VAC 60 Hz 1 second, from pins 1,2,3,4,5 to pins 6,7,8,9,10. 3000Nominal Primary Inductance, µH Measured at 1 V pk-pk, typical switching frequency, between pin 4 to pin 5, with all
other Windings open.1443
Tolerance, ±% Tolerance of Primary Inductance 7,0Maximum Primary Leakage, µH Measured between Pin 4 to Pin 5, with all other Windings shorted. 14,43
Although the design of the software considered safety guidelines, it is the user's responsibility to ensure that the user's power supply design meets all applicable safetyrequirements of user's product.
The products and applications illustrated herein (including circuits external to the products and transformer construction) may be covered by one or more U.S. and foreignpatents or potentially by pending U.S. and foreign patent applications assigned to Power Integrations. A complete list of Power Integrations' patents may be found atwww.power.com.