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Description
VIPAC Arrays are a highly flexible system of DC input, power building blocks that can be configured with as many as four user-definable outputs on a low-profile, coldplate chassis. Using Vicor’s configuration tool, designers are able to specify VIPAC Arrays with inputs of 24, 28, 48, 72, 110, 150, 300 or 375 Vdc and outputs from 2 to 54 Vdc at power levels up to 600 Watts per output. VIPAC Arrays are ideal for use in distributed and modular power systems where power density and reliable operation are critical. A current share option is available on single output models enabling them to be used in applications requiring high power / redundancy. Fully connectorized input and output terminations speed system installation and a versatile coldplate chassis simplifies thermal management.
Specifications
Input Voltages:
- 24 Vdc
- 28 Vdc
- 48 Vdc
- 72 Vdc
- 110 Vdc
- 150 Vdc
- 300 Vdc
- 375 Vdc
Output Voltages:
- 2 – 54 Vdc
Output Power:
- Up to 750 W
Dimensions:
- See mechanical drawing on data sheet
Features
- Single, dual, triple and quad outputs
- Fully connectorized input & output for simplified hook up
- Rugged, low profile, coldplate chassis
- High temperature capability
- Optional finned heat sinks available
Design Guides / Manuals
Maxi-Mini-Micro Data Sheet Directory
To view individual family data sheets for available intermediate power levels, click on the links.
Note: All power values are in Watts
* The 375 Vdc Maxi module is also available in output voltages of 32 V and 54 V @ 600 W
Application Notes
- Component Power Solutions for Industrial High Voltage Applications
- Wide Range Trimming with Variable Loads
- High Efficiency Battery Charger Using Power Components
- Using Modular DC-DC Converters to Meet European Standards for Railway Applications
- Adjustable Latching Output Over Current Circuit
- Hot Swap Capability Eliminates Down Time
Design Guides / Manuals
Safety Approvals
Note: 24, 28, 48, 72, 110, and 150 V input VIPAC Arrays are designed primarily for military COTS and industrial applications and do not carry safety agency approvals.
Mechanical Drawings
| 2-D VIPAC Array Drawings (Configuration “A”) | ||||
| Drwg. Number | Description | Download | RoHS | |
| 24822 | Outline drawing for VIPAC Array Configuration “A” | DXF | PDF |  |
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| 3-D VIPAC Array Drawings Configuration “A” (referring to drawing number 24822) | ||||
| Using LugMate, 1 Output | STEP | 3D PDF | |||
| Using LugMate, 2 Outputs | STEP | 3D PDF | |||
| Using PlugMate, 1 Output | STEP | 3D PDF | |||
| Using PlugMate, 2 Outputs | STEP | 3D PDF | |||
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| 2-D VIPAC Array Drawings (Configuration “B”) | ||||
| Drwg. Number | Description | Download | RoHS | |
| 24823 | Outline drawing for VIPAC Array Configuration “B” | DXF | PDF | |
|
| 3-D VIPAC Array Drawings Configuration “B” (referring to drawing number 24823) | ||||
| Using LugMate, 2 Outputs | STEP | 3D PDF | |||
| Using LugMate, 3 Outputs | STEP | 3D PDF | |||
| Using PlugMate, 2 Outputs | STEP | 3D PDF | |||
| Using PlugMate, 3 Outputs | STEP | 3D PDF | |||
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| 2-D VIPAC Array Drawings (Configuration “C”) | ||||
| Drwg. Number | Description | Download | RoHS | |
| 24824 | Outline drawing for VIPAC Array Configuration “C” | DXF | PDF | |
|
| 3-D VIPAC Array Drawings Configuration “C” (referring to drawing number 24824) | ||||
| Using LugMate, 2 Outputs | STEP | 3D PDF | |||
| Using LugMate, 3 Outputs | STEP | 3D PDF | |||
| Using PlugMate, 2 Outputs | STEP | 3D PDF | |||
| Using PlugMate, 3 Outputs | STEP | 3D PDF | |||
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| 2-D VIPAC Array Drawings (Configuration “D”) | ||||
| Drwg. Number | Description | Download | RoHS | |
| 24825 | Outline drawing for VIPAC Array Configuration “D” | DXF | PDF | |
|
| 3-D VIPAC Array Drawings Configuration “D” (referring to drawing number 24825) | ||||
| Using LugMate, 1 Output | STEP | 3D PDF | |||
| Using PlugMate, 1 Output | STEP | 3D PDF | |||
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| 2-D VIPAC Array Drawings (Configuration “E”) | ||||
| Drwg. Number | Description | Download | RoHS | |
| 24826 | Outline drawing for VIPAC Array Configuration “E” | DXF | PDF | |
|
| 3-D VIPAC Array Drawings Configuration “E” (referring to drawing number 24826) | ||||
| Using LugMate, 2 Outputs | STEP | 3D PDF | |||
| Using LugMate, 3 Outputs | STEP | 3D PDF | |||
| Using PlugMate, 2 Outputs | STEP | 3D PDF | |||
| Using PlugMate, 3 Outputs | STEP | 3D PDF | |||
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| 2-D VIPAC Array Drawings (Configuration “F”) | ||||
| Drwg. Number | Description | Download | RoHS | |
| 24827 | Outline drawing for VIPAC Array Configuration “F” | DXF | PDF | |
|
| 3-D VIPAC Array Drawings Configuration “F” (referring to drawing number 24827) | ||||
| Using LugMate, 2 Outputs | STEP | 3D PDF | |||
| Using LugMate, 3 Outputs | STEP | 3D PDF | |||
| Using LugMate, 4 Outputs | STEP | 3D PDF | |||
| Using PlugMate, 2 Outputs | STEP | 3D PDF | |||
| Using PlugMate, 3 Outputs | STEP | 3D PDF | |||
| Using PlugMate, 4 Outputs | STEP | 3D PDF | |||
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| 2-D VIPAC Array Drawings (Configuration “G”) | ||||
| Drwg. Number | Description | Download | RoHS | |
| 25335 | Outline drawing for VIPAC Array Configuration “G” | DXF | PDF | |
|
| 3-D VIPAC Array Drawings Configuration “G” (referring to drawing number 25335) | ||||
| Using LugMate, 1 Output | STEP | 3D PDF | |||
| Using PlugMate, 1 Output | STEP | 3D PDF | |||
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| 2-D VIPAC Array Drawings (Configuration “H”) | ||||
| Drwg. Number | Description | Download | RoHS | |
| 25336 | Outline drawing for VIPAC Array Configuration “H” | DXF | PDF | |
|
| 3-D VIPAC Array Drawings Configuration “H” (referring to drawing number 25336) | ||||
| Using LugMate, 1 Output | STEP | 3D PDF | |||
| Using LugMate, 2 Outputs | STEP | 3D PDF | |||
| Using PlugMate, 1 Output | STEP | 3D PDF | |||
| Using PlugMate, 2 Outputs | STEP | 3D PDF | |||
DC Input Filters
- FIAM – Filter Input Attenuator Module – DC input, front-end module providing transient protection, inrush current limiting and EMI filtering for Maxi, Mini and Mico DC-DC converters.
- M-FIAM – Filter Input Attenuator Module – DC input, front-end module providing transient protection, inrush current limiting and EMI filtering for Maxi, Mini, and Micro DC-DC converters.
| M-FIAM Model | Module Compatibility | Input Voltage | Output Current | Transient Compliance | Data Sheet | ||||||||||
| M-FIAM3 | 300 Vin Maxi, Mini, Micro | 180 – 375 Vdc | 3 Amps | MIL-STD-704E/F | |||||||||||
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| M-FIAM5B | 24 / 28 Vin Maxi, Mini, Micro | 14 – 36 Vdc | 20 Amps | MIL-STD-704E/F | |||||||||||
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| M-FIAM9 | 24 / 28 Vin Maxi, Mini, Micro | 10 – 36 Vdc | 18 Amps | MIL-STD-704A-F MIL-STD-1275A/B/D |
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Output Filters
- MicroRAM – Output Ripple Attenuator Module – The MicoRAM conbines both active and passive filtering to achieve greater than 40 dB of noise attenuation from over a range of 3 to 30 Vdc.
- QPO Family Output Filters – QPO filters use active filtering to reduce power supply ripple and noise in a 1.0″ x 1.0″ (25 x 25 mm) surface mount package.
Connectors
| Description | P/N | RoHS | TechnicalDrawing | |||||
 |
Input Connnector Kit | 24828 | |
LugMates
PlugMates
| Description | P/N | RoHS | Technical Drawing | |||||
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Maxi PlugMate Housing (for 24 Pins) | 25044 | |
– | ||||
| Maxi PlugMate Pins (24) | 24796 | |
– | |||||
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| Maxi PlugMate Connector Kit | 25061* | |
– | |||||
| – | ||||||||
| * Includes Housing and (24) Pins | – | |||||||
| – | ||||||||
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| – | ||||||||
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Mini PlugMate Housing (for 18 Pins) | 25050 | |
– | ||||
| Mini PlugMate Pins (18) | 24796 | |
– | |||||
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| Mini PlugMate Connector Kit | 25067* | |
– | |||||
| – | ||||||||
| * Includes Housing and (18) Pins | – | |||||||
| – | ||||||||
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| – | ||||||||
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Micro PlugMate Housing (for 8 Pins) | 25056 | |
– | ||||
| Micro PlugMate Pins (8) | 24796 | |
– | |||||
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| Micro PlugMate Connector Kit | 25073* | |
– | |||||
| – | ||||||||
| * Includes Housing and (8) Pins | – | |||||||
Standoffs
| Description | P/N | RoHS |
Technical Drawing
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Long Standoff Kit | 23709R | |
– | ||||
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Short Standoff Kit | 23710R | |
– | ||||
Thermal Management
| Longitudinal Heat Sinks | |||||||||
| All Heat Sinks are RoHS Compatible |
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| Description | Model Type | P/N | 3D Model Drawings | TechnicalDrawing | |||||
 |
Dual Mini | VA-A | 32161 | STEP | 3D PDF | |||||
| Singlle Mini / Dual Micro | VA-B | 32161 | STEP | 3D PDF | ||||||
| Triple Micro | VA-C | 32161 | STEP | 3D PDF | ||||||
| Single Maxi | VA-D | 32161 | STEP | 3D PDF | ||||||
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Dual Mini / Single Micro | VA-E | 32176 | STEP | 3D PDF | |||||
| Quad Micro | VA-F | 32176 | STEP | 3D PDF | ||||||
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Single Mini | VA-G | 32177 | STEP | 3D PDF | |||||
| Dual Micro | VA-G | 32177 | STEP | 3D PDF | ||||||
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| Transverse Heat Sinks | |||||||||
| All Heat Sinks are RoHS Compatible |
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| Description | Model Type | P/N | 3D Model Drawings | TechnicalDrawing | |||||
 |
Dual Mini | VA-A | 32178 | STEP | 3D PDF | |||||
| Singlle Mini / Dual Micro | VA-B | 32178 | STEP | 3D PDF | ||||||
| Triple Micro | VA-C | 32178 | STEP | 3D PDF | ||||||
| Single Maxi | VA-D | 32178 | STEP | 3D PDF | ||||||
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Dual Mini / Single Micro | VA-E | 32179 | STEP | 3D PDF | |||||
| Quad Micro | VA-F | 32179 | STEP | 3D PDF | ||||||
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Single Mini | VA-G | 32180 | STEP | 3D PDF | |||||
| Dual Micro | VA-G | 32180 | STEP | 3D PDF | ||||||