MVAC400-12AFT - Murata Power Solutions

MVAC400 Series

400W 3" x 5" High Density AC-

DC Power Supply

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MVAC400.B03 Page 1 of 9

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ORDERING GUIDE

Model Number Natural Convection Cooling

Forced Air Cooling Main Output

(V1)

Fan Output

(V2)

Aux Output

(V3)

MVAC400-12AF

250W 400W @ 250LFM

12V

12V 5V

MVAC400-24AF

24V

MVAC400-48AF

50V

MVAC400-12AFD

12V

MVAC400-24AFD

24V

MVAC400-48AFD

50V

MVAC400-24AFT*

24V

MVAC400-24AFJT*#

24V

MVAC400-12AFR*

12V

MVAC400-12AFT*

12V

MVAC-COVER

Optional cover kit assembly; see MVAC-COVER datasheet for details.

Refer to page 2 for current sharing details for MVAC400-xxAFD and MVAC400-xxAFR models.

* CCC Certification is not available for these models.

JST : B2P3-VH Series AC Input Connector

Molex Input Connector Variant Shown

FEATURES



IEC60601 Ed 3 Medical (2 X MOPP Pri-Sec)

EN60950 ITE safety approved



400W compact high density

3" x 5" standard footprint

High efficiency up to 94%

Remote sense

Remote On/Off, Power OK



Universal AC input with active PFC

Less than 1U high – 1.4"

Convection cooled operation up to 250W



Isolated 12V@1A fan output

Isolated 5V@2A standby output

RoHS compliant

Active inrush protection



Current sharing option

DESCRIPTION

The MVAC400 series switching power supplies utilize

advanced component and circuit technologies to

deliver high efficiency. Designed for medical,

computing, communications, telecom and other OEM

applications to satisfy 1U height design

considerations, the MVAC400 Series measures only

3.0" x 5.0" x 1.40". All models offer universal AC

input with active power factor correction (PFC) and

compliance to worldwide safety and EMC standards.

Available now at

www.murata-ps.com/en/3d/acdc.html

INPUT CHARACTERISTICS

Parameter

Conditions

Min.

Typ.

Max.

Units

Input Voltage Operating Range

Single phase

115/230

264

Vac

127

300

Vdc

Input Frequency

50/60

Turn-on Input Voltage

Input rising

Vac

Turn-off Input Voltage

Input falling

Input Current

90Vac input, full load all outputs

5.5

No Load Input Power

(PS_ON = OFF, 5V_Aux = 0A)

1.5

2.0

Inrush Current

At 264Vac, at 25°C cold start

Apk

Power Factor

At 230Vac, full load

0.98

OUTPUT CHARACTERISTICS

Model Number

Main Output

Voltage (V1)

Load Current

Maximum Load

Capacitance

Line, Load, Cross

Regulation6

Typical Efficiency

@230Vac

MVAC400-12AFx

12V

0 to 33.3A

0 to 2200µF

± 1%

93%

MVAC400-24AFxx 24V 0 to 16.7A 0 to 470µF ± 1% 93%

MVAC400-48AFx

50V

0 to 8.0A

0 to 150µF

± 1%

94%

MAIN OUTPUT CHARACTERISTICS (ALL MODELS)

Parameter Conditions Typ. Max. Units

Transient Response

50% load step, 1A/µsec slew rate

± 5

Settling Time to 1% of Nominal 500 µsec

Turn On Delay

After application of input power

sec

Output Voltage Rise Monotonic5 50 msec

Output Holdup

120Vac/60Hz, full load

Temperature Coefficient 0.02 %/°C

Ripple Voltage & Noise1

Remote Sense

Compensates for up to 0.5V of lead drop with

remote sense connected. Protected against

short circuit and reverse connection.

500 mV

Hot Swap Transients10

All outputs remain in regulation

± 10

AUXILIARY OUTPUT CHARACTERISTICS (ALL MODELS)

Auxiliary Output

Aux Output

Voltage

Load Current Load Capacitance

Line, Load, Cross

Regulation

Ripple Voltage &

Noise

Fan (V2) 12V 0 to 1A 0 to 220µF ± 10% 2%

Aux (V3)

0 to 2A

0 to 220µF

± 5%

For

full details go to

www

.murata-ps.com/rohs

Test Certificate

And Test Report

To Be Discontinued* *LAST TIME BUY: 4/1/2018.

MVAC400 Series

400W 3" x 5" High Density AC-DC Power Supply Converter

www.murata-ps.com/support

MVAC400.B03 Page 2 of 3

ENVIRONMENTAL CHARACTERISTICS

Parameter Conditions Min. Typ. Max. Units

Storage Temperature Range

-40

°C

Operating Temperature Range See power rating curves -10

Start up -20

Operating Humidity Non-condensing 10

95 %

Operating Altitude

-200

5000 m

MTBF Telcordia SR-332 M1C3 @25°C 474K

Hours

Shock Operating, MIL-HBK-810E Complies

Non-operating, MIL-HBK-810E Complies

Operational Vibration IEC-68-2-27 standard Complies to levels of IEC721-3-2

Safety – Medical Standards

2 x MOPP (Primary-Secondary)

IEC60601-1 (Ed. 3) – CB Cert and Report

ANSI/AAMI ES60601-1 (2005+C1:09+A2:10)

CAN/CSA 22.2 No. 60601-1 (2008) 3rd Edition

EN60601-1:2006+CORR:2010

Safety – ITE Standards

UL60950-1, 2nd Edition, 2011-12-19

CSA22.2 No.60950-1-07, 2nd Edition, 2001-12.

EN60950-1:2006+A11:2009/A1/2010/A12:2011

IEC 60950 (ed.2), IEC60950 (ed.2); am1

CE Marking per LVD

Warranty 2 years

Outside Dimensions 3.0" x 5.0" x 1.4" (76.2mm x 127mm x 35.6mm)

Weight (typ.) 0.8lbs (362.87g)

RESIDUAL RISK (PER ISO 14971 & IEC60601-1) FOR USER CONSIDERATION

Fault Condition

Residual Risk

Complies Contact your Murata salesperson for details

PROTECTION CHARACTERISTICS

Parameter Conditions Min. Typ. Max. Units

Over Voltage Protection4

V1 (main output) latching 110

125 %

V3 (aux output) latching 5.5

7.5 V

Over Current Protection4

V1, hiccup mode 110

130

%A max

V3, auto-recovery 110

150

Over Temperature Protection Auto-recovery

Complies

Remote Sense Short Circuit Protection

Complies

Remote Sense Reverse Connection Protection

Complies

ISOLATION CHARACTERISTICS

Parameter Conditions

Min.

Typ.

Max.

Units

Isolation Primary to Chassis

1500

Vac

Primary to Secondary (2xMOPP)

4000

Secondary to Chassis

500

Output to Output

500

Earth Leakage Current (under single fault condition) 264Vac, 60Hz, 25°C

300

µA

Earth Leakage Current (under normal conditions) 264Vac, 60Hz, 25°C

150

µA

CURRENT SHARING OPTION – MVAC400-xxAFD AND MVAC400-xxAFR

Model Number

Description

MVAC400-12AFD

MVAC400-24AFD

MVAC400-48AFD

MVAC400-12AFR

Main Output: Current share is achieved using the droop method. Nominal output voltage is achieved at 50% load and output voltage increases/drops at a

rate of:

• 30mv per amp for the 12V output•

• 120mV per amp for the 24V output

• 500mV per amp for the 50V output.

Startup of parallel power supplies is not internally synchronized. If more than 400W combined power is needed, start-up synchronization must be provided

by using a common PS_ON signal. To account for ±10% full load current sharing accuracy and the reduction in full load output voltage due to droop,

available output power must be derated by 15% when units are operated in parallel. Current sharing can be achieved with or without remote sense

connected to the common load.

If ORing protection is desired, use the AFR model or if the AFD model is selected please contact Murata sales for external ORing FET board or external

ORing

FET reference circuit design (also see Applications Note ACAN-42).

Aux (V3) output can be tied together for redundancy but total combined output power must not exceed 10W, external ORing devices must be used. Fan (V2)

can be tied together for redundancy but total com load must not exceed 12W, external ORing devices must be used.

MVAC400 Series

400W 3" x 5" High Density AC-DC Power Supply Converter

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MVAC400.B03 Page 3 of 3

EMISSIONS AND IMMUNITY

Characteristic Standard Compliance

Input Current Harmonics

IEC/EN 61000-3-2

Class A

Voltage Fluctuation and Flicker IEC/EN 61000-3-3 Complies

Conducted Emissions EN 55022 Class B

FCC Part 15

Class B

ESD Immunity IEC/EN 61000-4-2 Level 4, Criterion 2

Radiated Field Immunity IEC/EN 61000-4-3 Level 3, Criterion A

Electrical Fast Transient Immunity IEC/EN 61000-4-4 Level 4, Criterion A

Surge Immunity IEC/EN 61000-4-5 Level 3, Criterion A

Radiated Field Conducted Immunity IEC/EN 61000-4-6 Level 3, 10V/m, Criterion A

Magnetic Field Immunity

IEC/EN 61000-4-8

Level 3, Criterion A

Voltage dips, interruptions IEC/EN 61000-4-11 Level 3, Criterion B

EMI CONSIDERATIONS

For optimum EMI performance, the power supply should be mounted to a metal plate grounded to all 4 mounting holes of the power supply. To comply with safety standards,

this plate must be properly grounded to protective earth (see mechanical dimension notes). Pre-compliance testing has shown the stand-alone power supply to comply with

EN55022 class A radiated emissions. Class B radiated emissions are achievable with a metal enclosure. Radiated emission results vary with system enclosure and cable routing

paths.

CONSIDE

SAFETY CONSIDERATIONS

1. This power supply is a component level power supply intended for use in Class I or Class II applications. Secondary ground traces need to be suitably

isolated from primary ground traces when used in Class II applications.

2. When the power supply is used in Class II equipment, all ground traces and components connected to the primary side are considered primary for spacing

and insulation considerations.

IONS

STATUS AND CONTROL SIGNALS

Parameter Models Conditions

PS_ON

MVAC400-xxAF

MVAC400-xxAFD

MVAC400-xxAFR

This pin must be pulled low (sink current >2mA) to +5V_AUX_RTN to turn on the main and Fan (V2) output. The +5V_AUX output is independent of

the PS_ON signal, and comes up automatically when the input AC or input DC voltage is applied within their specified operating ranges.

MVAC400-xxAFT

MVAC400-xxAFJT

This pin is pulled high internally and so all three outputs (main, Fan output and +5V_AUX) come up automatically when the input AC or input DC

voltage is applied within their specified operating ranges.

Pulling this pin low (sink current >2mA) to +5V_AUX_RTN will disable the main and fan outputs.

PWR_OK

All Models Open collector logic goes high 50-200ms after the main output is within regulation; it goes low at least 6msecs before loss of regulation. Internal

10K pull up to +5V_Aux is provided. Applications using the PWR_OK signal should maintain a minimum load of 5W on the main or fan output.

1. Noise and ripple is measured at an oscilloscope jack on the output, 20MHz bandwidth, and with

0.1µF ceramic and 10µF aluminum electrolytic capacitors across the output pins.

2. Unless otherwise specified all measurements are taken at 120Vac input and 25°C ambient

temperature.

3. Fan (V2) regulation band applies from 0.1A to 1A load with a minimum of 10W load on the main

(V1) output.

4. Fan (V2) has overvoltage protection (tracking V1) and short circuit protection. Overloading the Fan

(V2) output can result in permanent damage to the unit.

5. 24V and 50V models may exhibit up to 5% turn on overshoot for loads less than 4% of full load.

6. Load regulation for droop version models (MVAC400-xxAFD and MVAC400-xxAFR) is based the

calculated droop voltage ±1.5% (see current sharing section for droop characteristics).

No load Input power varies by model and by input line. Measurement is difficult to make due to burst

mode operation. Please contact Murata sales if additional information is required.

All three output returns are isolated from each other (see isolation characteristics section); the

returns may be tied together externally.

Load steps beginning from combined loads on the main and fan outputs of less than 5W may

result in a transient undershoot outside of the specification limits.

10.

For MVAC400-xxAFR models only: Measured with 220µF capacitance across main output.

PART NUMBER STRUCTURE

yyy

hhhh

Murata Manufacturing Corp.

Form Factor Outline

A = 2″x4″; 3″x5″ or 4″x7″

Modification Code Options

A = Aux 5V Standby Voltage

F = Aux 12V Fan Output

D = Droop Current Share

J = JST AC Input Connector Variant

T = Terminal Output Connector

R = Terminal Output Connector, with Internal ORING Solution

and Droop Current Share

Outline Detail Main Output Voltage

B & D = 2″x4″ (12, 24, 27, 48)

C = 3″x5″

F = 4″x7″ Output Power (Watts)

(40, 65, 120, 160, 250, 400 or 750)

MVAC400 Series

400W 3" x 5" High Density AC-DC Power Supply Converter

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MVAC400.B03 Page 4 of 3

PERFORMANCE DATA

Inrush Current

Time: 100 msec/div, Ch1: 500 V/div, Ch4: 20 A/div, Vin: 264 VAC, Ipk = 15.1A

AC applied at peak of sine wave

MVAC400 Series

400W 3" x 5" High Density AC-DC Power Supply Converter

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MVAC400.B03 Page 5 of 3

Output Power (Watts)

Static Pressure (in.

w.g.)

THERMAL

CONSIDERA

TIONS

System thermal management is critical to the performance and reliability of the MVAC series power supplies. Performance derating curves are provided

which can be used as a guideline for what can be achieved in a system configuration with controlled airflow at various input voltage conditions.

The air flow curves are generated using an AMCA 210-99 and ASHRAE 51-1999 compliant wind tunnel with heated inlet air and a controlled CFM

providing a duct test section having a calculated average LFM. A correlation between the test setup and the actual system environment is paramount to

understanding what can be achieved in an actual system. In a power supply of this density, cooling air moving both through the unit as well as around the

unit strongly influences local temperatures. The wind tunnel test setup was constructed to produce a flow with a slight back pressure to induce both flow

conditions by providing a small gap between the power supply and duct walls of 0.5" (13mm). The optimal and characterized airflow direction is from the

input connector to the output connector (see diagram below). The P-Q flow curve for this test setup is also shown below.

13mm [0.5in] all sides

Power Supply

0.0100

P-Q CURVE, DUCTED FLOW

0.0075

0.0050

Ambient

mper

Meas

ement

0.0025

Output Connector Input Connector

64mm [2.5in]

0.0000

2.5

7.5

12.5

17.5

22.5

AIRFLOW-(CFM

@ 0.075 lbs/cu ft air

density)

The natural convection data is obtained from a horizontally mounted power supply with un-obstructed flow at room temperature. At elevated temperature

the power supply data is taken while it is surrounded by a large vented enclosure to minimize forced cross flows inherent in the elevated temperature test

system.

450

Power Rating at 230Vac

450

Power Rating at 120Vac

400

350

300

250

200

150

100

10 20 30 40 50 60 70

Ambient Temperature (Degrees C)

350LFM

250LFM

Nat Conv

300

250

200

150

100

10 20 30 40 50 60 70

Ambient Temperature (Degrees C)

500LFM

350LFM

250LFM

Nat Conv

450

Power Rating at 100Vac

450

Power Rating at 90Vac

400

350

300

250

200

150

100

10 20 30 40 50 60 70

Ambient Temperature (Degrees C)

500LFM

350LFM

250LFM

Nat Conv

300

250

200

150

100

10 20 30 40 50 60 70

Ambient Temperature (Degrees C)

500LFM

350LFM

250LFM

Nat Conv

Airflow

Output Power (Watts)

MVAC400 Series

400W 3" x 5" High Density AC-DC Power Supply Converter

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MVAC400.B03 Page 6 of 3

WIRING DIAGRAM FOR OUTPUT

Note: For parallel (current share) operation it is required to connect the sharing power supplies in parallel (+DC out connected together and DC out Return connected together on sharing power

supplies. Since each output has an identical “droop” share characteristic then each output will intrinsically share the total load current.

WIRING DIAGRAM FOR OUTPUT

APPLICATION NOTE

Document Number Description Link

ACAN-42 MVAC Series External ORing FET Reference Circuit www.murata-ps.com/data/apnotes/acan-42.pdf

MVAC400 Series

400W 3" x 5" High Density AC-DC Power Supply Converter

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MVAC400.B03 Page 7 of 3

MECHANICAL DIMENSIONS – MVAC400-xxAF AND MVAC400-xxAFD

SAFETY CONSIDERATION NOTES:

1. Protective bonding conductor from the end product protective earthing terminal must be tied to TB1. For optimum EMI performance, while maintaining Class

I safety isolation all 4 mounting holes must be tied to the end product protective earthing terminal. To maintain Class II safety isolation mounting holes MTG1

and MTG2 need to be isolated from protective earth and should use standoffs of non-conductive material.

2. This power supply requires mounting standoffs of minimum 6mm in height. If there is risk of chassis deformation or shorter standoff height is required, an

appropriate insulator must be used under the power supply with adequate extension beyond the outline of the power supply. In all cases, the applicable

safety standards must be applied to ensure proper creepage and clearance requirements are met.

3. The primary heatsink is considered a live primary circuit, and should not be touched. It is recommended that the primary heatsink be kept at least

3.5mm from chassis, and 7mm from secondary circuits. In all cases, the applicable safety standards must be applied to ensure proper creepage and

clearance requirements are met.

4. This product is subject to the following operating requirements and the Life and Safety Critical Application Sales Policy: Refer to:

http://www.murata-ps.com/requirements/

5. Used only in non-tropical conditions.

6. Double pole/neutral fusing.

INPUT/OUTPUT CONNECTOR AND SIGNAL SPECIFICATION AND MATING CONNECTORS – MVAC400-xxAF and MVAC400-xxAFD

Connector

Description

Mating Housing

Crimp terminal/pins

Input Connector J1:

Molex 26-62-4030

AC Neutral

Molex 0009930300

Molex 0008500105 (18-24 AWG) Molex

0008500107 (22-26 AWG)

AC Line

Output Connector J2:

Molex 39-28-1123

1,2,3,4,5,6

+DC_OUT

Molex 0039012125

Molex 0039000038

7,8,9,10,11,12

+DC_OUT_RTN

Output Connector J3:

Molex 90130-1108

+5V_AUX

Molex 0901420008

Molex 0901190109

PWR_OK

+12V_FAN_RTN

PS_ON

+Remote Sense

-Remote Sense

+12V_FAN

+5V_AUX_RTN

MVAC400 Series

400W 3" x 5" High Density AC-DC Power Supply Converter

www.murata-ps.com/support

MVAC400.B03 Page 8 of 3

MECHANICAL DIMENSIONS – MVAC400-xxAFT AND MVAC400-xxAFR

SAFETY CONSIDERATION NOTES:

1. Protective bonding conductor from the end product protective earthing terminal must be tied to TB1. For optimum EMI performance, while maintaining

Class I safety isolation all 4 mounting holes must be tied to the end product protective earthing terminal. To maintain Class II safety isolation mounting

holes MTG1 and MTG2 need to be isolated from protective earth and should use standoffs of non-conductive material.

2. This power supply requires mounting standoffs of minimum 6mm in height. If there is risk of chassis deformation or shorter standoff height is required,

an appropriate insulator must be used under the power supply with adequate extension beyond the outline of the power supply. In all cases, the

applicable safety standards must be applied to ensure proper creepage and clearance requirements are met.

3. The primary heatsink is considered a live primary circuit, and should not be touched. It is recommended that the primary heatsink be kept at least

3.5mm from chassis, and 7mm from secondary circuits. In all cases, the applicable safety standards must be applied to ensure proper creepage and

clearance requirements are met.

4. This product is subject to the following operating requirements and the Life and Safety Critical Application Sales Policy: Refer to:

http://www.murata-ps.com/requirements/

5. Used only in non-tropical conditions.

6. Double pole/neutral fusing.

INPUT/OUTPUT CONNECTOR AND SIGNAL SPECIFICATION AND MATING CONNECTORS – MVAC400-xxAFT AND MVAC400-xxAFR

Connector

Description

Mating Housing

Crimp terminal/pins

Input Connector J1:

Molex 26-62-4030

AC Neutral

Molex 0009930300

Molex 0008500105 (18-24 AWG)

Molex 0008500107 (22-26 AWG)

AC Line

Output Connector J2:

+DC_OUT

6-32 machine screws

–

+DC_OUT_RTN

Output Connector J3:

Molex 90130-1108

+5V_AUX

Molex 0901420008

Molex 0901190109

PWR_OK

+12V_FAN_RTN

PS_ON

+Remote Sense

-Remote Sense

+12V_FAN

+5V_AUX_RTN

MVAC400 Series

400W 3" x 5" High Density AC-DC Power Supply Converter

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MVAC400.B03 Page 9 of 3

MECHANICAL DIMENSIONS – MVAC400-xxAFJT