• Skip to primary navigation
  • Skip to main content
  • Skip to primary sidebar
  • Skip to footer
  • Subscribe
  • Advertise

Power Electronic Tips

Power Electronic News, Editorial, Video and Resources

  • Products
    • Power Supplies
    • AC-DC
    • DC-DC
    • Battery Management
    • Capacitors
    • Magnetics
    • MOSFETS
    • Power Management
    • RF Power
    • Resistors
    • Transformers
    • Transistors
  • Applications
    • 5G
    • AI
    • Automotive
    • EV Engineering
    • LED Lighting
    • Industrial
    • IoT
    • Wireless
  • Learn
    • eBooks / Tech Tips
    • EE Training Days
    • FAQ
    • Learning Center
    • Tech Toolboxes
    • Webinars & Digital Events
  • Resources
    • Design Guide Library
    • Digital Issues
    • Engineering Diversity & Inclusion
    • LEAP Awards
    • Podcasts
    • White Papers
    • Design Fast
  • Video
    • EE Videos & Interviews
    • Teardown Videos
  • EE Forums
    • EDABoard.com
    • Electro-Tech-Online.com
  • Engineeering Training Days
  • Newsetter Subscription

Bidirectional power supplies support new UPS requirements, Part 2

July 19, 2022 By Bill Schweber

Bidirectional power supplies dynamically direct power from multiple sources to different loads, some of which are also power sources at other times.

In recent years, there’s has been a dramatic increase in the need for bidirectional AC/DC and DC/DC power supplies, in addition to the unidirectional supply of a traditional UPS. That supply takes a source (such as the AC line or battery, or in some cases, a high-voltage DC line) and converts and regulates it to provide a DC-rail output for a load. In contrast, the bidirectional supply has multiple independent power sources. It can transfer energy from one to another as needed or available, as well as to the system’s primary load itself.

Bidirectionality with two power sources is not the same as simply having two independent power sources in parallel for higher capacity or in a redundancy arrangement where either can supply the system load. Instead, it involves continuous management of power flow from one source to the other as determined by the availability and load conditions. The load on each source may be independent of the other source’s load.

In contrast to a basic offline or online UPS, modern power subsystems and their applications must encompass a multiplicity of power sources and loads. Some of these will be a source at one time and load at another time depending on shifting of power availability and needs.

The objective is to take power from where it is available at any given time (such as from high-voltage AC or DC lines or solar panels) and send it to a primary load. If excess power is available, it can also go to storage (a battery, in most cases) for later use, but also be able to draw on the battery if the primary source is unavailable. (Figure 1).

Fig 1: In one basic configuration, the bidirectional supply allows energy to flow from a high-voltage supply at the grid to a low-voltage battery and vice versa. (Image: TDK)

Note that the local power user (the local load) can be an individual residence, neighborhood, commercial office building, or even a medical/industrial setting. Some excess power may come via regeneration, such as from elevators or industrial motors.

In short: it can get complicated. While there are differences in the specifics of sources, loads, their magnitude, their priorities, and the load’s dynamic range and criticality, they all have similar issues from a high-level perspective. Of course, there are differences – and these can be significant – due to power capacity and sizing of their various elements and functional criticality.

There’s another consideration when using a bidirectional converter. For line-operated systems, the previously captured and stored energy can supply additional power needed at the startup when large amounts of torque are required (Figure 2). This topology saves energy overall, and it allows for a smaller AC-line power subsystem, as the peak demand on the line-side supply will be reduced.

Fig 2: A suitable bidirectional supply such as this TDK EZA unit allows batteries to be charged, then supplement AC-line power to a large motor during high-demand phases. (Image: TDK)

A similar arrangement is used in battery-backup situations. The AC line powers the load and charges the batteries, which are also charged via solar panels. When AC power fails, the batteries power the load through the bidirectional converter and can still be charged by the panels. Thus, the system has power flowing to where it is needed from where it is available.

The use of bidirectional supplies is not limited to high-voltage/high-current applications. Many of the latest cars, including those with traditional internal combustion engines (ICE), now use a dual-battery power system. These have a 12-V battery for lower-power loads, a 48-V battery pack for efficiency, and smaller conductors for higher-power loads (Figure 3).

Fig 3: Bidirectional supplies are now used in automobiles to shift available energy between the 48-V battery used for heavier loads and the 12-V battery for lighter loads. (Image: Texas Instruments)

In this dual-source/dual-rail topology, it is necessary to continually assess if each battery has sufficient capacity to support its loads, and transfer power at any time from the battery which has adequate capacity to the one which may be lacking it. This is the case even though the ICE alternator will be charging both batteries but cannot do so quickly enough.

Today’s power components and the systems they support are expected to be compact, efficient, and reliable. At the same time, new functional demands are being placed on them to handle more types of sources and loads under a complex set of power-flow scenarios. Key to this challenge is the development of bidirectional power-supply and power-management units.

EE World Related Content

Putting supercapacitors to work
Energy storage by the Farad, Part 1: Supercapacitor basics
Energy storage by the Farad, Part 2: Supercapacitors & batteries
Energy storage by the Farad, Part 3: Hybrid supercapacitors
Applying large banks of supercapacitors
Supercapacitor ESR and optimal performance – Virtual Roundtable (part 1 of 2)
Supercapacitor specifications and lifetimes – Virtual Roundtable (part 2 of 2)
UPS provides long back-up times via lithium-iron-phosphate batteries
SiC 1,200-V power modules target EV charging, UPS apps
DC UPS family offers maintenance-free, supercapacitor energy storage

External References

  • Recom, “How to make a 10kW bidirectional AC/DC converter”
  • MEAN WELL, “Application of Bidirectional Switching Power Supply with Energy Recycle and AC Grid Function”
  • Vertiv Group Corp, “What Are the Different Types of UPS Systems?”
  • Unified Power, “Which UPS Topology is optimal for your environment?”
  • Schneider Electric, “The Different Types of UPS Systems”
  • EtechnoG, “Offline and Online UPS Block Diagram”
  • Cabling Installation and Maintenance, “A generator-friendly uninterruptible power supply”
  • This Old House, “Backup Power”
  • Elprocus, “Uninterruptible Power Supply Circuit Diagram and Working”
  • Green Tech Media, “Generac, the Backup Generator Giant, Launches Souped-Up Home Solar-Storage System”

 

You may also like:


  • Bidirectional power supplies support new UPS requirements: Part 1
  • supercaps
    Putting supercapacitors to work
  • supercapacitors
    Energy storage by the Farad, Part 3: Hybrid supercapacitors
  • supercapacitors
    Energy storage by the Farad, Part 2: Supercapacitors & batteries
  • supercapacitor basics
    Energy storage by the Farad, Part 1: Supercapacitor basics

Filed Under: FAQ, Featured, uninterruptible power sources Tagged With: FAQ

Primary Sidebar

Featured Contributions

Robust design for Variable Frequency Drives and starters

Meeting demand for hidden wearables via Schottky rectifiers

The case for vehicle 48 V power systems

GaN reliability milestones break through the silicon ceiling

Developing power architecture to support autonomous transportation

More Featured Contributions

EE LEARNING CENTER

EE Learning Center

EE TECH TOOLBOX

“ee
Tech Toolbox: 5G Technology
This Tech Toolbox covers the basics of 5G technology plus a story about how engineers designed and built a prototype DSL router mostly from old cellphone parts. Download this first 5G/wired/wireless communications Tech Toolbox to learn more!

EE ENGINEERING TRAINING DAYS

engineering
“power
EXPAND YOUR KNOWLEDGE AND STAY CONNECTED
Get the latest info on technologies, tools and strategies for EE professionals.
“bills

RSS Current EDABoard.com discussions

  • VHF radio
  • Phase shift full bridge with SiC FETs is irresponsible?
  • I think i have devised a new type of "super_transformer" for the Electricity grid?
  • Finding past posts on edaboard?
  • Industrial Relay Board Design for Motorcycle Use

RSS Current Electro-Tech-Online.com Discussions

  • Data is not transferring to Data register of SPI in MG32F157VCT6
  • Sump pit water alarm - Kicad 9
  • Pic18f25q10 osccon1 settings swordfish basic
  • Anyone jumped from Easyeda std to Easyeda pro?
  • turbo jet fan - feedback appreciated.

DesignFast

Component Selection Made Simple.

Try it Today
design fast globle

Footer

EE World Online Network

  • 5G Technology World
  • EE World Online
  • Engineers Garage
  • Analog IC Tips
  • Battery Power Tips
  • Connector Tips
  • DesignFast
  • EDA Board Forums
  • Electro Tech Online Forums
  • EV Engineering
  • Microcontroller Tips
  • Sensor Tips
  • Test and Measurement Tips

Power Electronic Tips

  • Subscribe to our newsletter
  • Advertise with us
  • Contact us
  • About us

Copyright © 2025 · WTWH Media LLC and its licensors. All rights reserved.
The material on this site may not be reproduced, distributed, transmitted, cached or otherwise used, except with the prior written permission of WTWH Media.

Privacy Policy