This system provides users with the ability to use COTS devices and have the overall system meet conducted mil spec EMI requirements without having to test each individual device to these requirements. Using 1 kW Power Processor modules, mounted into a 4U 19″ rack configuration, the 3-phase delta input power is converted into a 150 VDC bus, which is then used to power electronic devices connected to the system.
ACT’s Power Processor modules are designed utilizing a unique power factor correction circuit, which accepts MIL-STD-1399 section 300A input power and provides the MIL-STD-461E EMI compliance by isolating the COTS devices from the input power. A fully configured system is comprised of nine separate 1 kW module building blocks and an input EMI filter module.
Electrical | Environmental | Physical |
Input power: 115 V, 3 phase, 60 Hz Delta, Floating Neutral per MIL-STD-1399 section 300A | Temperature: 0º to 50º C Altitude: 15,000 ft. operating |
4U ModuleWeight: 110 lbs. |
Output Voltages: 150 VDC Output Power: 1 kW to 9 kW |
Vibration: MIL-STD-167, 4 to 20 Hz Shock: 15 g’s peak, 40 ms ½ sine wave |
Height: 6.969″ Depth: 21.063″ Width: 17.625″ |
EMI: MIL-STD-461E | Structure & Airborne Noise: MIL-STD-740-2 Type III | Modules: 9 max. |
Type | Output Voltage | Current | Power | Frequency |
---|---|---|---|---|
+150 VDC Module | +150 VDC +28 VDC |
6.7 A 0.6 A |
1 kW 17 W |
DC |
+12 VDC Module | +12 VDC | 6.7 A | 80 W | DC |
Square Wave Inverter Module | 150 Vp-p | 8 A | 1 kW | 60 Hz |
Sine Wave Inverter Module | 120 Vrms | 3.3 Arms | 400 W | 60 Hz |
Optimum EMI performance is achieved when three, six, or nine of the 1 kW power modules are selected. These configurations balance the power load across all three phases of the delta input power. The +150 VDC power bus generated by these modules can then be used to power any COTS device that has a PFC input power supply.
The inverter modules can be used to power devices that do not have an active PFC power supply. ACT has a growing number of custom modules that operate off the power bus. Depending on your unique requirements, ACT can rapidly develop a new module for your specific application.
If this power supply does not suit your specific needs, ACT can custom design a solution for you. Since 1981 ACT has designed and produced over 1,000 designs. ACT specializes in designing and manufacturing high voltage and low voltage power supplies to meet today’s most demanding environmental, performance, and miniaturization requirements.
Characteristics:
This 1 kW module can be combined to produce in excess of 9 KW of power when mounted with eight other modules in the 19″ 4U chassis designed by ACT. Each module contains an EMI filter and an active Power Factor Corrected (PFC) front end. It is designed to convert single-phase 115 VAC into a single bulk output voltage.
Designed and qualified to meet the EMI requirements of MIL-STD-461E, it provides the user a fully isolated output voltage, which can be utilized in a wide variety of different applications and configurations. Depending upon the current rating of the output connector selected, the output voltage can range from +48 VDC to +270 VDC.
The active PFC front end provides the >0.99% power factor and keeps the harmonic distortion from exceeding the required 3% in both single and three phase configurations. In three phase applications, the 1 KW modules can be configured such that the input power can be evenly balanced across all three phases. This configuration has been qualified to MIL-STD-461E in a number of different programs.
To increase the available output power and maintain optimum EMI performance 1 kW modules should be added in multiples of three and connected such that they are evenly balanced across the input phases.
Connecting the modules in parallel can provide increased output power in multiples of 1 kW. This is obtainable due to the module’s automatic load-sharing feature.
To achieve higher output voltages modules can be connected in series. For example, three standard +150 VDC modules can be connected in series to provide a +450 VDC, 3 KW output. This is made possible due to the complete electrical isolation of the module’s output.
These modules can provide N+1 redundancy in a number of configurations. For example in a configuration where a system needs 2 kW of power three modules are selected and connected in parallel. Because of the automatic load sharing under normal operation, each module will provide 1/3 of the output power. However, if one module fails the other two are capable of supplying the full output power requirements.
N+1 redundancy can also be provided in the event of the loss of one phase of a three-phase system. For example, three 1 kW modules are providing power to a 2 kW load. Each module is being supplied by one phase of the three phase input power. If one phase of input power is lost the module that is using this input power will stop functioning but the other two modules will automatically pick up the load.
By using the input circuit breakers modules can be added or removed from the rack without disrupting the system.
Each module contains enough energy storage to provide full output power for a minimum of 70 msec. In many cases, this can eliminate the need for a UPS system and satisfying system designers’ concerns with an automatic bus transfer (ABT).
Advanced Conversion Technology has also designed a series of modules that utilize the +150 VDC voltage bus to generate a variety of other DC output voltages and currents. Additionally, in those cases that need AC input power, ACT has developed sine wave and square wave inverter modules.