ECP150PS12

**ECP150 Series** 

> **AC-DC Power Supplies** LAP XP Power 

## 150 Watts 

- 100 W Convection-cooled 

- 150 W Forced-cooled 

- 2” x 4”Foot Print 

- Single Outputs from 12 V to 48 V 

- Built-in Fan Supply 

- <0.5 W No Load Input Power 

- 3 Year Warranty 

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Dimensions:<br>ECP150:<br>4.00 x 2.00 x 1.16” (101.6 x 50.8 x 29.5 mm)<br>**----- End of picture text -----**<br>


The ECP150 series minimises the no load power consumption and maximises efficiency to facilitate equipment design to meet the latest environmental legislation. Approved for medical and ITE applications, this range of single output AC/DC power supplies are packaged in a low profile 1.26” height with a foot print of just 2.0” by 4.0”. The ECP150 provides up to 150W force-cooled or 100W convection-cooled leading to very high power densities of 14.9W/in[3] or 9.9W/in[3] respectively. A 12V, 500mA fan supply is included in the design.The power supply contains two fuses and low leakage currents as required by medical applications and is safety approved to operate in a 70 °C ambient.The low profile and safety approvals covering ITE and medical standards along with conducted emissions meeting EN55011/22 level B allow the versatile ECP150 series to be used in a vast range of applications. 

Models & Ratings 

|Output Voltage|Output Current|Output Current|Ripple and Noise<br>pk-pk(2)|Fan Output|Efficiency(3)|Model Number|
|---|---|---|---|---|---|---|
||Convection-cooled|Forced-cooled(1)|||||
|12.0 V|8.33 A|12.50 A|120 mV|12 V/0.5 A|91%|ECP150PS12|
|15.0 V|6.67 A|10.00 A|150 mV|12 V/0.5 A|91%|ECP150PS15|
|24.0 V|4.17 A|6.25 A|240 mV|12 V/0.5 A|91%|ECP150PS24|
|28.0 V|3.50 A|5.40 A|280 mV|12 V/0.5 A|92%|ECP150PS28|
|48.0 V|2.08 A|3.10 A|480 mV|12 V/0.5 A|92%|ECP150PS48|



## ~~**Notes**~~ 

_1. Requires 10 CFM._ 

_2. Measured with 20 MHz bandwidth and 10 μ F electrolytic capacitor in parallel with 0.1 μ F ceramic capacitor_ 

_3. Minimum average efficiencies measured at 25%, 50%, 75% & 100% of 150 W load and 230 VAC input._ 

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$$ 4.00 (101.6) a<br>Voltage Adj.<br>3.75 (95.2 ) l<br>—<br>;r<br>1 TB3<br>(44.45)1.75 f TB1 NL a 31  Cyl Ps. fa l 1 e TB2 (50.8)2.00 |<br>ey|E[foooe o [oc] 000 [2°] 00N [Oo] S G | NG FXY el NAYSS2| E ni 6 0 ° t B n<br>0.134     (3.4) @<br>( oO =) oO 1.16 t<br>(29.5)<br>0.06 (1.6) 0.10 (2.5)<br>**----- End of picture text -----**<br>


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Input 

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|||||||||
|---|---|---|---|---|---|---|---|
|GC|Characteristic|Minimum|Typical|Maximum|Units|Notes & Conditions|
|Input Voltage - Operating|90|115/230|264|VAC|Derate output from 100% at 100 VAC to  90% at 90 VAC|
|a|a|ee|
|eG|Input Frequency|47|50/60|63|Hz|Agency approval 47-63 Hz|
|230 VAC, 100% load EN61000-3-2 class A|
|Power Factor|0.95|
|EN61000-3-2 class C > 60W|
|aeG|Input Current - Full Load|ee|1.5/0.75|ee|A|115/230 VAC|
|Ge|Inrush Current|60|GG|A|230 VAC cold start, 25 °C|
|Ds|Earth Leakage Current|GG|80/140|230|μ|A|115/230 VAC/50 Hz (Typ.), 264 VAC/60 Hz (Max.)|
|eG|No Load Input Power|0.5|W|
|Ge|Input Protection|F3.15 A/250 V Internal fuse fitted in line and neutral.|

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Output 

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|||||||||
|---|---|---|---|---|---|---|---|
|a|Characteristic|GO|Minimum|Typical|Maximum|Units|Notes & Conditions|
|CC|Output Voltage - V1|12|48|VDC|See Models and Ratings table|
|ee|Initial Set Accuracy|±1|%|V1 at 50% load, 115/230 VAC|
|Output Voltage Adjustment - V1|10|%|V1 only via potentiometer. See mech. details,  Vfan will track|
|eG|
|FsDe|Minimum Load|0|GGGeGO|A|
|pO|Start Up Delay|550|ms|115/230 VAC full load at 25° C. See fig. 3 & 4.|
|Rise Time|35|ms|
|De|eG|GGG|
|Hold Up Time|16|20|ms|At full load, 100 VAC, see fig. 5.|
|De|eeGG|GO|
|Drift|±0.02|%|After 20 min warm up|
|DeeeGG|GG|
|Line Regulation|±0.5|%|90-264 VAC|
|DeeeGG|GO|
|pO|Load Regulation|±0.5|%|0-100% load|
|Transient Response|4|%|Recovery within 1% in less than 500|μ|s|
|for a 50-75% and 75-50% load step|
|a|Over/Undershoot|ee|4|%|Full Load|
|De|GG|GO|
|Ripple & Noise|1|% pk-pk|20 MHz bandwidth & 10|μ|F electrolytic capacitor|
|in parallel with 0.1|μ|F ceramic capacitor, See fig. 6.|
|Ds|Overvoltage Protection|ee|115|sO|140|%|Vnom, recycle input to reset|
|De|GG|GO|
|Overload Protection|110|150|% I nom|See fig. 1.|
|DeeeGG|GG|
|Short Circuit Protection|Trip and Restart See fig. 2.|
|De|reGO|GO|
|Temperature Coefficient|0.02|%/ ° C|
|es|es|GQ|

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## **Output Overload Characteristic** 

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Figure. 1<br>ECP150PS12 ECP150PS24<br>Over Current Profile  Over Current Profile<br>Percent Overload  Percent Overload<br>100%  110%  120%  130%  140%  100%  110%  120%  130%  140%<br>12.1  24.2<br>11.9  24<br>11.7  a 100Vac 115Vac  23.8  100Vac 115Vac<br>11.5  a 230Vac 264Vac  23.6  a 230Vac 264Vac<br>11.3 11.1  23.4 23.2  aSt<br>12.5  —— 13.75  15  16.25  17.5  a a 6.25  6.875  7.5  8.125  8.75<br>Current (A)  Current (A)<br>Output Voltage (V)  Output Voltage (V)<br>**----- End of picture text -----**<br>


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## **Output Short Circuit Profile** 

Figure 2 ECP150PS12 

## **Output Start Up Time** 

Figure 3 ECP150PS12 100VAC full load 

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ECP150PS24<br>**----- End of picture text -----**<br>


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Output Rise Time<br>**----- End of picture text -----**<br>


Figure 4 ECP150PS12 100 VAC full load 

## **Output Hold Up Time** 

Figure 5 ECP150PS12 100VAC 100W load 

ECP150PS12 100VAC 150W load 

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## **Output Noise & Ripple** 

## Figure 6 

ECP150PS12 at 100VAC & 150W load Low Frequency 

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High Frequency<br>**----- End of picture text -----**<br>


## General 

|Characteristic|Minimum|Typical|Maximum|Units|Notes & Conditions|
|---|---|---|---|---|---|
|Efficiency||91||%|230 VAC Full load (see fig. 7 & 8)|
|Isolation: Input to Output<br>Input to Ground<br>Output to Ground|4000|||VAC|2 MOPP|
||1500|||VAC|1 MOPP|
||500|||VDC||
|Switching Frequency|||60|kHz|PFC ±10kHz|
||||60|kHz<br>Main Converters ±10kHz|Main Converters ±10kHz|
|Power Density|||14.9/9.9|W/in3|Forced / Convection-cooled|
|Mean Time Between Failure||300||kHrs|MIL-HDBK-217F, Notice 2 +25°C GB|
|Weight||0.51(230)||lb(g)||



## **Efficiency Vs Load** 

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100% 90%  |—z.— a . 100Vac input<br>Figure 7  — 115Vac input<br>ECP150PS12 a 230Vac input<br>80%  264Vac input<br>70%  Se<br>10  20  30  40  50  60  70  80  90  100<br>Load (%)<br>100%<br>Figure 8 ECP150PS24 90%  pp————— = —— 100Vac input 115Vac input<br>a 230Vac input<br>80%  264Vac input<br>70%  Se<br>10  20  30  40  50  60  70  80  90  100<br>Load (%)<br>Efficiency<br>Efficiency<br>**----- End of picture text -----**<br>


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|XP Power<br>**ECP150 Series**<br>**AC-DC Power Supplies**<br>Environmental<br>Characteristic<br>Minimum<br>Typical<br>Maximum<br>Units<br>Notes & Conditions<br>Operating Temperature<br>-20<br>+70<br>°C<br>See derating curve, fig.9<br>Storage Temperature<br>-40<br>+85<br>°C<br>Cooling<br>10<br>CFM<br>Forced Cooled > 100W<br>Humidity<br>5<br>95<br>%RH<br>Non-condensing<br>Operating Altitude<br>3000<br>m<br>Shock<br>±3 x 30g shocks in each plane, total 18 shocks.<br>30g = 11ms (+/- 0.5msecs), half sine. Conforms to<br>EN60068-2-27<br>Vibration<br>Single axis 10 - 500 Hz at 2g sweep and<br>endurance at resonance in all 3 planes.<br>Conforms to EN60068-2-6<br>~~=~~<br>~~a~~|XP Power<br>**ECP150 Series**<br>**AC-DC Power Supplies**<br>Environmental<br>Characteristic<br>Minimum<br>Typical<br>Maximum<br>Units<br>Notes & Conditions<br>Operating Temperature<br>-20<br>+70<br>°C<br>See derating curve, fig.9<br>Storage Temperature<br>-40<br>+85<br>°C<br>Cooling<br>10<br>CFM<br>Forced Cooled > 100W<br>Humidity<br>5<br>95<br>%RH<br>Non-condensing<br>Operating Altitude<br>3000<br>m<br>Shock<br>±3 x 30g shocks in each plane, total 18 shocks.<br>30g = 11ms (+/- 0.5msecs), half sine. Conforms to<br>EN60068-2-27<br>Vibration<br>Single axis 10 - 500 Hz at 2g sweep and<br>endurance at resonance in all 3 planes.<br>Conforms to EN60068-2-6<br>~~=~~<br>~~a~~|XP Power<br>**ECP150 Series**<br>**AC-DC Power Supplies**<br>Environmental<br>Characteristic<br>Minimum<br>Typical<br>Maximum<br>Units<br>Notes & Conditions<br>Operating Temperature<br>-20<br>+70<br>°C<br>See derating curve, fig.9<br>Storage Temperature<br>-40<br>+85<br>°C<br>Cooling<br>10<br>CFM<br>Forced Cooled > 100W<br>Humidity<br>5<br>95<br>%RH<br>Non-condensing<br>Operating Altitude<br>3000<br>m<br>Shock<br>±3 x 30g shocks in each plane, total 18 shocks.<br>30g = 11ms (+/- 0.5msecs), half sine. Conforms to<br>EN60068-2-27<br>Vibration<br>Single axis 10 - 500 Hz at 2g sweep and<br>endurance at resonance in all 3 planes.<br>Conforms to EN60068-2-6<br>~~=~~<br>~~a~~|XP Power<br>**ECP150 Series**<br>**AC-DC Power Supplies**<br>Environmental<br>Characteristic<br>Minimum<br>Typical<br>Maximum<br>Units<br>Notes & Conditions<br>Operating Temperature<br>-20<br>+70<br>°C<br>See derating curve, fig.9<br>Storage Temperature<br>-40<br>+85<br>°C<br>Cooling<br>10<br>CFM<br>Forced Cooled > 100W<br>Humidity<br>5<br>95<br>%RH<br>Non-condensing<br>Operating Altitude<br>3000<br>m<br>Shock<br>±3 x 30g shocks in each plane, total 18 shocks.<br>30g = 11ms (+/- 0.5msecs), half sine. Conforms to<br>EN60068-2-27<br>Vibration<br>Single axis 10 - 500 Hz at 2g sweep and<br>endurance at resonance in all 3 planes.<br>Conforms to EN60068-2-6<br>~~=~~<br>~~a~~|XP Power<br>**ECP150 Series**<br>**AC-DC Power Supplies**<br>Environmental<br>Characteristic<br>Minimum<br>Typical<br>Maximum<br>Units<br>Notes & Conditions<br>Operating Temperature<br>-20<br>+70<br>°C<br>See derating curve, fig.9<br>Storage Temperature<br>-40<br>+85<br>°C<br>Cooling<br>10<br>CFM<br>Forced Cooled > 100W<br>Humidity<br>5<br>95<br>%RH<br>Non-condensing<br>Operating Altitude<br>3000<br>m<br>Shock<br>±3 x 30g shocks in each plane, total 18 shocks.<br>30g = 11ms (+/- 0.5msecs), half sine. Conforms to<br>EN60068-2-27<br>Vibration<br>Single axis 10 - 500 Hz at 2g sweep and<br>endurance at resonance in all 3 planes.<br>Conforms to EN60068-2-6<br>~~=~~<br>~~a~~|XP Power<br>**ECP150 Series**<br>**AC-DC Power Supplies**<br>Environmental<br>Characteristic<br>Minimum<br>Typical<br>Maximum<br>Units<br>Notes & Conditions<br>Operating Temperature<br>-20<br>+70<br>°C<br>See derating curve, fig.9<br>Storage Temperature<br>-40<br>+85<br>°C<br>Cooling<br>10<br>CFM<br>Forced Cooled > 100W<br>Humidity<br>5<br>95<br>%RH<br>Non-condensing<br>Operating Altitude<br>3000<br>m<br>Shock<br>±3 x 30g shocks in each plane, total 18 shocks.<br>30g = 11ms (+/- 0.5msecs), half sine. Conforms to<br>EN60068-2-27<br>Vibration<br>Single axis 10 - 500 Hz at 2g sweep and<br>endurance at resonance in all 3 planes.<br>Conforms to EN60068-2-6<br>~~=~~<br>~~a~~|XP Power<br>**ECP150 Series**<br>**AC-DC Power Supplies**<br>Environmental<br>Characteristic<br>Minimum<br>Typical<br>Maximum<br>Units<br>Notes & Conditions<br>Operating Temperature<br>-20<br>+70<br>°C<br>See derating curve, fig.9<br>Storage Temperature<br>-40<br>+85<br>°C<br>Cooling<br>10<br>CFM<br>Forced Cooled > 100W<br>Humidity<br>5<br>95<br>%RH<br>Non-condensing<br>Operating Altitude<br>3000<br>m<br>Shock<br>±3 x 30g shocks in each plane, total 18 shocks.<br>30g = 11ms (+/- 0.5msecs), half sine. Conforms to<br>EN60068-2-27<br>Vibration<br>Single axis 10 - 500 Hz at 2g sweep and<br>endurance at resonance in all 3 planes.<br>Conforms to EN60068-2-6<br>~~=~~<br>~~a~~|XP Power<br>**ECP150 Series**<br>**AC-DC Power Supplies**<br>Environmental<br>Characteristic<br>Minimum<br>Typical<br>Maximum<br>Units<br>Notes & Conditions<br>Operating Temperature<br>-20<br>+70<br>°C<br>See derating curve, fig.9<br>Storage Temperature<br>-40<br>+85<br>°C<br>Cooling<br>10<br>CFM<br>Forced Cooled > 100W<br>Humidity<br>5<br>95<br>%RH<br>Non-condensing<br>Operating Altitude<br>3000<br>m<br>Shock<br>±3 x 30g shocks in each plane, total 18 shocks.<br>30g = 11ms (+/- 0.5msecs), half sine. Conforms to<br>EN60068-2-27<br>Vibration<br>Single axis 10 - 500 Hz at 2g sweep and<br>endurance at resonance in all 3 planes.<br>Conforms to EN60068-2-6<br>~~=~~<br>~~a~~|XP Power<br>**ECP150 Series**<br>**AC-DC Power Supplies**<br>Environmental<br>Characteristic<br>Minimum<br>Typical<br>Maximum<br>Units<br>Notes & Conditions<br>Operating Temperature<br>-20<br>+70<br>°C<br>See derating curve, fig.9<br>Storage Temperature<br>-40<br>+85<br>°C<br>Cooling<br>10<br>CFM<br>Forced Cooled > 100W<br>Humidity<br>5<br>95<br>%RH<br>Non-condensing<br>Operating Altitude<br>3000<br>m<br>Shock<br>±3 x 30g shocks in each plane, total 18 shocks.<br>30g = 11ms (+/- 0.5msecs), half sine. Conforms to<br>EN60068-2-27<br>Vibration<br>Single axis 10 - 500 Hz at 2g sweep and<br>endurance at resonance in all 3 planes.<br>Conforms to EN60068-2-6<br>~~=~~<br>~~a~~|XP Power<br>**ECP150 Series**<br>**AC-DC Power Supplies**<br>Environmental<br>Characteristic<br>Minimum<br>Typical<br>Maximum<br>Units<br>Notes & Conditions<br>Operating Temperature<br>-20<br>+70<br>°C<br>See derating curve, fig.9<br>Storage Temperature<br>-40<br>+85<br>°C<br>Cooling<br>10<br>CFM<br>Forced Cooled > 100W<br>Humidity<br>5<br>95<br>%RH<br>Non-condensing<br>Operating Altitude<br>3000<br>m<br>Shock<br>±3 x 30g shocks in each plane, total 18 shocks.<br>30g = 11ms (+/- 0.5msecs), half sine. Conforms to<br>EN60068-2-27<br>Vibration<br>Single axis 10 - 500 Hz at 2g sweep and<br>endurance at resonance in all 3 planes.<br>Conforms to EN60068-2-6<br>~~=~~<br>~~a~~|
|---|---|---|---|---|---|---|---|---|---|
||**Temperature Derating Curve**|||||||||
|Figure 9||100||||||||
|||50<br>Output Load (%)|High Line Only|||||||
|||0||||||||
|||-40|-30<br>0||+50||+70|||
|Ambient Temperature (ºC)<br>EMC: Immunity<br>EMC: Emissions<br>Phenomenon<br>Standard<br>Test Level<br>Criteria<br>Notes & Conditions<br>Conducted<br>EN55011/22<br>Class B<br>Radiated<br>EN55011/22<br>Class A<br>Harmonic Current<br>EN61000-3-2<br>Class A<br> Class C for loads above 60W<br>~~SSSSS~~||||||||||
||Phenomenon|Standard||Test Level|||Criteria||Notes & Conditions|
||Voltage Fluctuations|EN61000-3-3||||||||
||Low Voltage PSU EMC|EN61204-3||High severity level||as below||||
||Radiated Immunity|EN61000-4-3||3|||A|||
||EFT/Burst|EN61000-4-4||3|||A|||
||Surges|EN61000-4-5||Installation class 3|||A|||
||Conducted|EN61000-4-6||3|||A|||
|||||Dip > 95% (0 VAC), 8.3ms|||A|||
|||EN61000-4-11||Dip  30% (70 VAC), 416ms|||A|||
|||||Dip> 95%(0 VAC), 4160ms|||B|||
|||EN55035<br>(240 VAC)||Dip> 95%(0 VAC), 10.0ms<br>Dip30%(168 VAC), 500ms|||A<br>A|||
|||||Dip> 95%(0 VAC), 5000ms|||B|||
||Dips and Interruptions|EN60601-1-2||Dip> 95%(0 VAC), 10.0ms<br>Dip60%(40 VAC), 100ms|||A<br>B|||
|||(100 VAC||Dip30%(70 VAC), 500ms|||A|||
|||||Dip> 95%(0 VAC), 5000ms|||B|||
|||||Dip> 95%(0 VAC), 10.0ms|||A|||
|||EN60601-1-2||Dip60%(96 VAC), 100ms|||A|||
|||(240 VAC)||Dip30%(168 VAC), 500ms|||A|||
|||||Dip > 95% (0 VAC), 5000ms|||B|||



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## Safety Approvals 

|Safety Agency|Safety Standard|Notes & Conditions|
|---|---|---|
|CB Report|IEC62368-1|Audio/Video, Information and Communication Technology Equipment|
||IEC60601-1 Ed 3 Including Risk Management|Medical|
|UL|UL62368-1, CSA 22.2 No.62368-1-07 Ed, 2011-12|Audio/Video, Information and Communication Technology Equipment|
||ANSI/AAMI ES60601-1:2005 & CSA C22.2, No.60601-1:08|Medical|
|EN|EN62368-1:2014/A11:2017|Audio/Video, Information and Communication Technology Equipment|
||EN60601-1/A12:2006|Medical|
|CE<br>Meets all applicable directives|Meets all applicable directives||
|UKCA<br>Meets all applicable legislation|Meets all applicable legislation||



Means of Protection Category Primary to Secondary 2 x MOPP (Means of Patient Protection) IEC60601-1 Ed 3 Primary to Earth 1 x MOPP (Means of Patient Protection) ~~ee~~ Mechanical Details & Connectivity ~~MME RO s—s——ssCisS~~ 

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TB1 - Input Connector<br>Pin 1 Line<br>Pin 2 Not Fitted 4.00 (101.6)<br>Pin 3 Neutral Voltage Adj.<br>3.75 (95.2 )<br>Mates with JST housing<br>VHR-3N and JST Series<br>SVH-21T-P1.1 crimp terminals<br>1 TB3<br>Mounting holes marked with  N 3 1<br> must be connected to safety earth 1.75 TB1 2.00<br>. (44.45) TOT L 1 TB2 (50.8)<br>TB2 - Output Connector<br>Pin 1 +Vout<br>6<br>Pin 2 +Vout<br>Pin 3 +Vout | ee<br>Seis 000 0 0 Q<br>Pin 4 -Vout<br>Pin 5 -Vout<br>0.134     (3.4)<br>Pin 6 -Vout<br>= Beehi ve |<br>Mates with JST housing<br>VHR-6N and JST Series<br>SVH-21T-P1.1 crimp terminals<br>1.16<br>jo8 0<br>(29.5)<br>TB3 - Fan Connector<br>Pin 1 Fan +<br>Pin 2 Fan -<br>Mates with Molex housing   0.06 (1.6)<br>22-01-1022 and 2759 crimp   0.10 (2.5)<br>terminals<br>**----- End of picture text -----**<br>


## ~~**Notes**~~ 

1. All dimensions shown in inches (mm). Tolerance: ±0.02 (0.5) 

2. Weight: 0.42 lbs (230 g) approx. 

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## Thermal Considerations ~~Me~~ 

In order to ensure safe operation of the PSU in the end-use equipment, the temperature of the components listed in the table below must not be exceeded. Temperature should be monitored using K type thermocouples placed on the hottest part of the component (out of direct air flow). See Mechanical Details for component locations. 

|Temperature Measurements (At Maximum Ambient)|Temperature Measurements (At Maximum Ambient)|
|---|---|
|Component|Max Temperature °C|
|TR1 Coil|110°C|
|L4 Coil|120°C|
|Q1 Body|120°C|
|Q2 Body|120°C|
|C1|105°C|
|C20|105°C|



Service Life ~~SCee~~ 

The estimated service life of the ECP150 is determined by the cooling arrangements and load conditions experienced in the end application. Due to the uncertain nature of the end application this estimated service life is based on the actual measured temperature of a key capacitor with in the product when installed by the end application, 

The graph below expresses the estimated lifetime of a given component temperature and assumes continuous operation at this temperature. 

## **Estimated Service Life vs Component Temperature** 

Figure 10 

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70000<br>60000<br>50000<br>40000<br>C20<br>30000<br>C1<br>20000<br>10000<br>0<br>105 95 85 75 65 55<br>C1 & C20 Temperature (ºC)<br>Lifetime (Hrs)<br>**----- End of picture text -----**<br>


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