How do UPS power systems work?

26 Aug.,2024

 

What is a UPS and How Does It Work? - Unified Power

A Guide to USPs: Types and Benefits

Across today&#;s highly connected and data-driven business landscape, the need for continuous, clean power cannot be overstated. Even the briefest downtime can be devastating to an organization, regardless of its size or vertical. The price tag for downtime is estimated at $5,600 per minute, and unplanned incidents can result in equipment damage, data loss, missed opportunities and tarnished reputation.

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Thankfully, an uninterruptible power system (UPS) is one of the simplest, most cost-effective solutions to help companies avoid the unwelcome consequences of downtime. But with several types of systems available, the challenge is selecting one that best matches your needs and budget.

What Is a UPS System?

A UPS system is a backup solution that supplies power in the event of a utility failure. By supplying an adequate window to safely shut down sensitive equipment, a UPS helps prevent data loss and minimizes the stress of a hard shutdown on electronics.

Protecting equipment against a complete power loss isn&#;t the only reason you need a UPS. Depending on the UPS model, these systems also shield connected devices from common power problems and unsafe output voltage fluctuations that can damage electronics, reduce life span and affect performance.

How Does a UPS Work?

How Does a UPS Work?

A UPS works by converting AC power to DC power and storing it in a battery. Then, it converts the DC power back to AC power, running it to your building&#;s AC outlets. Your connected devices will continue to operate on the stored battery power, giving you time to save your work and shut down the computer.

Essentially a battery in a box, a UPS powers the devices plugged into its AC outlets when electricity flow drops to an inadequate voltage or a complete outage occurs. In a power emergency, the UPS electrical system instantly switches to the battery to provide a continuous power source for the length of the battery, which varies by system for periods ranging from minutes to hours. Additionally, the conversion process removes most of the line noise from the AC outlet.

Depending on the size and technology of the unit, a UPS can protect a single computer up to an entire data center. Essential for mission-critical environments, a UPS keeps computer systems and IT equipment safe and operational during a power loss until generators can be activated or protected devices, such as servers and network components, can be properly shut down. This helps prevent lost data while saving work-in-progress.

In addition to delivering backup power during a utility failure, UPSs also afford varying degrees of protection against other damaging power problems, including:

  • Voltage sags
  • Surges
  • Brownouts
  • Line noise
  • Frequency variations
  • Overvoltage conditions
  • Switching transients
  • Harmonic distortion 

Types of UPS Systems

UPS systems are not created equal. Rather, there are three primary topologies &#; standby, line-interactive and online. Each UPS topology delivers varying levels of protection against power problems, achieving the result in a unique manner while placing differing frequency demands on the battery.

Standby UPS

Also called an &#;offline&#; or &#;passive&#; UPS, standby technology offers the most basic type of protection, allowing equipment to run on incoming utility power until it detects a problem. In a standby UPS model, connected devices receive utility power through a direct AC connection. The unit essentially remains on hold until backup power is needed.

A standby UPS will switch to the battery to safeguard connected equipment when power fails, as well as adjust for routine sags and surges. The transfer time generally occurs in milliseconds after a power loss, and although the switch is not instantaneous, it usually won&#;t interrupt the flow of power to equipment. If a lengthy outage is expected, the UPS&#;s battery backup power will allow for safe shutdowns so equipment and data remain protected.

Because standby topology does not buffer equipment against other common power anomalies, it is best suited for non-critical and less demanding home network and office environments that are not subjected to frequent disruptions. While standby UPSs are the least expensive type, the downside to this topology is that it frequently resorts to the battery, which can reduce runtime and service life.

Line-Interactive UPS

A UPS with line-interactive topology is designed to shield connected devices from power failures, sags and surges like a standby model, while also protecting against voltage spikes and drops.

Typically used to safeguard enterprise network and IT applications, the line-interactive UPS is controlled by a microprocessor that monitors the quality of incoming power and reacts to fluctuations. In addition to providing more protection than standby UPSs, line-interactive units offer better power conditioning and regulation, helping prolong battery life.

One of the biggest advantages of line-interactive topology is that it compensates for undervoltage and overvoltage circumstances without using the batteries. Under normal power conditions, line-interactive UPSs pass input power to connected equipment through a surge/noise filter and voltage regulator, while an inverter charges the battery for emergency use during an outage. 

However, if the voltage fluctuates outside of a safe window, the UPS relies on built-in automatic voltage regulation (AVR) to increase or decrease the output voltage to an acceptable level. As long as the input voltage remains within a safe range, line-interactive UPSs regulate the output voltage without using battery power.

This advantage prevents frequent switching to the battery, which can drain reserve power intended for an outage and reduce battery lifespan. During an outage, the line-interactive UPS converts the stored battery power into regulated AC output power to support the connected equipment load.

Online UPS

While standby and line-interactive UPS models provide varying degrees of power conditioning, an online or double-conversion UPS is designed to deliver continuous protection against all nine of the most common power problems, supplying consistent, clean power regardless of any incoming instabilities. To create a power supply without any electrical interference, the output voltage of an online UPS is entirely regenerated by a sequence of AC to DC conversion, followed by DC to AC conversion.

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During erratic power or fleeting disturbances when AC input power falls outside of preset tolerances for line-interactive mode, the online UPS switches to online double-conversion mode, completely isolating equipment from incoming power. If power fails altogether, or the input power exceeds the tolerances of the rectifier, the UPS will rely on the battery to keep loads operating, then convert back to high-efficiency mode when it is safe.

Online UPSs are the optimal choice for mission-critical applications or those involving highly sensitive equipment, such as data centers, communications hubs and other installations where continuous, clean power is a business-critical requirement. They are also beneficial in environments that are particularly prone to dirty power.

Benefits of a UPS Power Supply

There are numerous benefits to deploying a UPS, including:

1. Minimized Effects From Power Outages

UPSs protect against utility power failures, which occur on a dramatically increasing basis. While outages can result from a wide variety of issues &#; including automobile accidents, animal interference and overtaxed power grids &#; severe weather ranks as the top cause of power failures in the United States. From hurricanes to heat waves and flooding to freezing rain, weather is leaving organizations in the dark for longer than it has in the past, largely due to climate change fueling more violent storms.           

2. Protection Against Power Variances

In addition to keeping equipment operational during a power loss, a UPS also acts as a filter to shield devices against variances in the power supply, which can damage sensitive equipment like computers and network gear.

Depending on the topology, a UPS allows only a steady stream of clean power to reach attached devices, helping safeguard against common power anomalies that can damage equipment. Additionally, battery backup prevents data loss and provides time to save work in progress during outages, surges or other power variances.

3. Increased Peace of Mind

Finally, a UPS provides confidence that your organization can avoid the financial cost, customer frustration and business disruption caused by network downtime &#; and you can&#;t put a price tag on peace of mind. Whether protecting a network closet, a few server racks or an entire data center, it is imperative to safeguard against equipment damage, downtime and data loss.



Find UPSs From Unified Power

It&#;s more critical than ever for organizations of every size to protect their operations against the impacts of downtime. While all three UPS topologies outlined above meet the input voltage requirements for IT equipment, there are significant differences in both performance and demands on the battery.

The best topology for your organization depends on numerous factors, including the level of reliability and availability required, the type of equipment being protected and the overall application/environment. If you need assistance determining the optimal topology and UPS model for your environment, Unified Power can help you compare and identify systems. Contact us today and let us know how we can help!

How does an Uninterruptible Power Supply (UPS) work?

An uninterruptible power supply (UPS), also known as a battery backup, provides backup power when your regular power source fails or voltage drops to an unacceptable level. A UPS allows for the safe, orderly shutdown of a computer and connected equipment. The size and design of a UPS determine how long it will supply power.

UPS Topologies

Different UPS topologies provide specific levels of power protection. A CyberPower UPS will belong to one of these three topologies: standby, line interactive, and double-conversion.

Standby is the most basic UPS topology. A standby UPS resorts to battery backup power in the event of common power problems such as a blackout, voltage sag, or voltage surge. When incoming utility power drops below or surges above safe voltage levels, the UPS switches to DC battery power and then inverts it to AC power to run connected equipment. These models are designed for consumer electronics, entry-level computers, POS systems, security systems, and other basic electronic equipment.

A line interactive UPS incorporates technology which allows it to correct minor power fluctuations (under-voltages and over voltages) without switching to battery. This type of UPS has an autotransformer that regulates low voltages (e.g., brownouts) and over voltages (e.g., swells) without having to switch to battery. Line interactive UPS models are typically used for consumer electronics, PCs, gaming systems, home theater electronics, network equipment, and entry-to-mid-range servers. They provide power during such events as a blackout, voltage sag, voltage surge, or over-voltage.

A double-conversion (online) UPS provides consistent, clean, and near perfect power regardless of the condition of incoming power. This UPS converts incoming AC power to DC, and then back to AC. UPS systems with this technology operate on isolated DC power 100 percent of the time and have a zero transfer time because they never need to switch to DC power. Double-conversion UPS systems are designed to protect mission-critical IT equipment, data center installations, high-end servers, large telecom installations and storage applications, and advanced network equipment from damage caused by a power blackout, voltage sag, voltage surge, over voltage, voltage spike, frequency noise, frequency variation, or harmonic distortion.

UPS output waveforms

CyberPower UPS systems have either sine wave or simulated sine wave output, depending upon the model.

 

Sine wave output: The highest quality waveform output is sine wave, which is a smooth, repetitive oscillation of AC power. Enterprise-level UPS systems produce sine wave power to operate sensitive electronic equipment. Sine wave output ensures that equipment utilizing Active PFC power supplies do not shut down when switching from utility power to battery power.

Simulated sine wave output: An approximated sine wave output waveform. It uses pulse wave modulation to generate a stepped, approximated sine wave to supply more cost-effective battery backup power for equipment that does not require sine wave output. The technology used to produce this type of power output is less expensive to manufacture and is common in standby and line interactive UPS systems.

Where can you learn more?

CyberPower offers standby, line interactive, and double-conversion UPS solutions. Find information about our UPS systems here.

Are you interested in learning more about Power industry UPS solutions? Contact us today to secure an expert consultation!