Latest Generators/UPS Articles

Battery Backup Explained

Battery backup delivers uninterruptible power to critical loads using UPS topology, inverter systems, and energy storage, providing voltage regulation, surge protection, and runtime during outages for sensitive equipment and industrial control circuits.

What Is Battery Backup?

A battery backup is an energy storage system that supplies temporary power to loads during outages, stabilizing voltage.

✅ Maintains critical load power during grid interruptions

✅ Provides surge protection, power conditioning, and voltage regulation

✅ Supports UPS topology: standby, line-interactive, or online

Battery backup is crucial in providing uninterrupted power for our devices and equipment during power outages. By understanding the different types of backup systems, battery capacity, and maintenance, you can make a well-informed decision to protect your home or business from unexpected power interruptions. So embrace the benefits of modern battery backup solutions and never be left in the dark again. For critical facilities, understanding how an emergency power supply integrates with battery backup can inform resilience planning.

We often take the constant supply of electricity for granted. However, power outages are unavoidable and can leave us scrambling for alternative energy sources. This is where battery backup solutions come into play, providing an essential lifeline in times of need. Many organizations adopt an uninterruptible power supply to ensure seamless continuity during brief outages.

Battery backup systems, or Uninterruptible Power Supply (UPS) systems, provide emergency power when the primary electrical supply fails. These systems can range from small portable power banks to larger installations that support businesses during power outages. A well-designed battery backup ensures that your essential devices and equipment stay up and running, minimizing downtime and preventing data loss. If you're new to the technology, this overview of what a UPS system is clarifies core components and typical use cases.

To choose the right UPS for your needs, consider factors such as the power requirements of your devices, the desired backup time, and your budget. An essential distinction to understand when selecting a backup solution is the difference between a UPS and a standard battery backup system. While both provide emergency power, a UPS offers a seamless transition without interruption to the connected devices. This feature is especially crucial for sensitive equipment like computers and servers. For a structured checklist, consult these tips for selecting a UPS system before finalizing your purchase.

Battery backup capacity plays a significant role in determining the duration of backup time during a power outage. Capacity is measured in ampere-hours (Ah) or watt-hours (Wh), which defines how much energy a battery can store. The larger the capacity, the longer it will last during a power outage. However, remember that larger-capacity batteries may require more space and come at a higher cost. To estimate runtime, review guidance on how long battery backups last under varying loads and conditions.

One of the most popular types of rechargeable batteries used in backup systems is the lithium-ion battery. These batteries boast a high energy density, allowing them to store more power in a smaller form factor. They also have a longer lifespan than traditional lead-acid batteries, making them an ideal choice for backup systems. Compatibility between lithium-ion modules and your UPS power supply should be verified for charging profiles and safety features.

Maintaining and prolonging the life of your battery backup involves a few essential steps. Please make sure that you store the batteries in a cool, dry place, away from direct sunlight and extreme temperatures. Regularly check the battery connections for any signs of corrosion and clean them if needed. Replacing your batteries according to the manufacturer's guidelines is crucial, as their efficiency decreases over time.

Solar power systems are increasingly integrated with battery backups as renewable energy sources become more prevalent. A solar battery backup stores energy generated by solar panels during the day, allowing you to tap into that stored power during a power outage or when energy demand is high. You can create a sustainable and eco-friendly power management system by combining solar power and battery storage. In hybrid systems, choosing an appropriate UPS uninterruptible power supply topology helps balance efficiency, transfer time, and protection.

Now that you understand battery backup solutions better, you can make an informed decision when selecting a system to safeguard your essential devices and equipment during power outages. You can ensure continuous power supply and minimize downtime by considering factors like UPS versus standard backup procedures, battery capacity, and type, and integrating solar power when possible.

Electrical Generators and UPS Channel

Automatic Transfer Switch

An automatic transfer switch (ATS) seamlessly shifts electrical load from the utility to a backup generator during power outages. It ensures continuous power, improves safety, and protects sensitive equipment from unexpected power loss or fluctuations.

What is an Automatic Transfer Switch?

An automatic transfer switch (ATS) is invaluable for maintaining a reliable power supply in unpredictable outages. It:

✅ Automatically switches power from utility to generator during outages

✅ Enhances safety and prevents electrical backfeed

✅ Protects equipment by ensuring uninterrupted power flow

Emergency Generator Standby Power Training

Power Quality Analysis Training

Request a Free Emergency Generator Training Quotation

Technical Depth: Controllers and Monitoring Logic

Modern automatic transfer switches rely on intelligent control systems to ensure seamless and safe operation during power outages. These controllers are the "brains" of the automatic transfer switch, constantly monitoring utility and generator power for any abnormalities such as voltage drops, frequency fluctuations, or phase loss. By using microprocessor-based technology, the ATS can make precise decisions and execute transfers with minimal delay.

Modern ATS use advanced microprocessor-based controllers that continuously monitor utility power for voltage, frequency, and phase stability. These controllers initiate a transfer only when they detect abnormal conditions, preventing unnecessary switching. Features such as time-delay settings, load testing, event logging, and communication interfaces for remote monitoring enhance reliability and operational control, particularly for facilities with sensitive equipment. For a deeper look into reliable backup power solutions, check out our section on emergency backup generators.

ATS Types and Transition Mechanics

ATSs are designed to handle different power transfer needs depending on the criticality of the load and the application. The transition method determines how the automatic transfer switch switches from the utility power to the backup generator and back again. Each type of transition offers unique advantages in terms of reliability, smoothness of power delivery, and equipment protection.

There are three primary transition types in automatic transfer switches:

Open Transition (Break-Before-Make): Disconnects the load from the utility before connecting to the generator. This avoids overlap and is commonly used in residential and standard commercial systems.
Closed Transition (Make-Before-Break): Briefly connects both power sources during transfer, minimizing interruptions. Ideal for hospitals and critical facilities.
Delayed Transition: Adds a pause between transfers to allow motor loads or residual currents to discharge, reducing equipment wear and electrical stress.

Choosing the right transition type depends on load sensitivity and operational requirements.

Automatic Transfer Switch Key Details

Feature	Description	Applications/Benefits
Controller Technology	Microprocessor-based controllers monitor voltage, frequency, and phase stability to trigger smooth transfers.	Prevents false transfers, supports remote monitoring, improves reliability.
Open Transition	Break-before-make operation disconnects utility power before connecting to the generator.	Standard residential and commercial systems.
Closed Transition	Make-before-break operation allows brief overlap between power sources.	Hospitals, data centers, and critical operations where no power interruption is acceptable.
Delayed Transition	Introduces a pause between power sources to dissipate residual energy from motors or inductive loads.	Industrial facilities with heavy motor loads.
Generator Sizing	ATS must be rated to handle generator output and inrush currents.	Prevents overloads and ensures stable power transfer.
NEMA Enclosures	Protects ATS components based on environment (NEMA 1 indoor, NEMA 3R/4 outdoor).	Ensures durability and compliance with installation standards.
Load Management Features	Includes load shedding or prioritization for critical circuits when generator capacity is limited.	Maximizes backup power efficiency.
Amperage Ratings	ATS must match service amperage (residential, commercial, or industrial).	Guarantees safe and effective operation.

Selection Criteria for an ATS

Selecting the correct ATS requires a careful evaluation of the power needs, system design, and environmental factors. The right ATS ensures that the generator and connected loads operate safely and efficiently during an outage. Factors such as load priorities, installation environment, and power quality features can significantly impact performance and reliability.

When selecting an automatic transfer switch, consider:

Generator Sizing: The ATS must match the generator’s maximum output, taking into account surge loads and starting currents.
NEMA Enclosure Types: Use NEMA 1 for indoor environments, NEMA 3R or 4 for outdoor or harsh conditions.
Load Management Features: Some ATS models provide load shedding or prioritization to manage generator capacity.
Amperage Ratings: Match the switch to your total service amperage for safe operation in residential, commercial, or industrial settings.

Learn how different battery backup systems work to keep critical loads powered during outages.

By selecting the right switch, ensuring correct installation and maintenance, and adhering to safety best practices, you can enjoy the benefits of a backup power system and the peace of mind it provides.

Power outages

Power outages can cause significant disruptions to our daily lives and business operations. Ensuring a consistent and uninterrupted power supply is crucial in today's world, which relies heavily on technology and electricity. An ATS is a reliable solution for maintaining power during outages.

An automatic transfer switch is an essential component of any backup power system. It facilitates seamless power transfer between the primary power source and a standby generator during an outage. By doing so, the ATS helps maintain a continuous flow of electricity, safeguarding homes and businesses from the negative impacts of power loss.

When selecting an appropriate automatic transfer switch, factors such as generator power capacity, load type, and intended application are crucial. Consulting with an electrical switchgear expert is a wise step in making an informed decision. Consider the voltage and amperage ratings, as well as the intended use of the switch, whether for residential, commercial, or industrial purposes. Switchgear systems may offer various features, such as remote monitoring and built-in diagnostics, catering to different requirements. Our article on emergency power supply explains how these systems provide seamless transitions during utility failures.

Automatic transfer switches and manual transfer switches

Automatic transfer switches and manual transfer switches differ in their operational modes. While a manual transfer switch necessitates physical engagement by an individual to shift the load between the main power source and the backup generator, an ATS performs this task automatically, ensuring a more efficient and dependable response.

Proper installation and maintenance of an ATS are crucial for its optimal performance and longevity. Although a qualified electrician should always perform installation, end-users can perform basic maintenance tasks, such as routine inspections, cleaning, and testing. Specialized servicing should be left to professionals to ensure the ATS remains in peak condition.

The main components of an ATS include the transfer switch, a controller, and a power source. The transfer switch, either open transition or closed transition, connects and disconnects the load between the utility power and the standby generator. The controller monitors voltage levels and initiates the load transfer when required. Finally, the power source, typically a backup generator, supplies power during an outage.

An ATS is vital for ensuring an uninterrupted power supply during an outage. First, it detects a power outage and signals the standby generator to start. Once the generator runs, the ATS conducts a load transfer from the primary power source to the backup power system. After power is restored, the ATS switches the load back to the utility power and shuts down the generator. This smooth process minimizes the detrimental effects of power outages.

Automatic Transfer Switch In Critical Facilities

Critical facilities, such as hospitals and data centers, require a bypass isolation switch for added redundancy and maintenance flexibility. The bypass isolation switch enables the ATS to be serviced or replaced without interrupting power to the facility.

Single-phase and three-phase automatic transfer switches are the two primary types, with their usage varying according to application and load requirements. Single-phase switches are commonly used in residential settings, whereas three-phase switches are typically employed in commercial and industrial applications.

Safety should always be a top priority when working with an ATS. Please ensure that a licensed electrician installs the switch and follows the manufacturer's guidelines for maintenance and testing. Additionally, appropriate personal protective equipment should be used when handling electrical switchgear, and all applicable local and national electrical codes should be followed.

Frequently Asked Questions

What is an ATS?

An ATS is an electrical device that automatically transfers power from the utility to a backup generator when an outage occurs, ensuring uninterrupted power.

How does an ATS work?

An ATS continuously monitors incoming utility power. If it detects a failure, it triggers the generator to start and shifts the electrical load. When utility power returns, it smoothly switches back.

Which ATS is best for home or commercial use?

Homes typically use single-phase ATS units with lower amperage, while commercial or industrial facilities require three-phase models designed for larger loads and critical operations.

Generators and UPS Systems Channel

UPS Ratings — Not So Apparent

UPS ratings define uninterruptible power supply capacity, kVA/kW, power factor, efficiency, and battery runtime, guiding load sizing, surge protection, and runtime planning for data centers, industrial controls, servers, and critical infrastructure.

What Are UPS Ratings?

UPS ratings define UPS capacity—kVA/kW, power factor, efficiency—and runtime to align loads with required reliability.

✅ Measure kVA, kW, and power factor to size loads accurately.

✅ Check efficiency curves and THD for cleaner, cooler operation.

✅ Verify battery runtime at specified load, temperature, and aging.

The uninterruptible power supply (UPS) industry is very competitive. Products are often selected based on the cost per volt-ampere (VA) of output power. In such markets, assessing designs such as high-efficiency UPS systems can clarify total cost of ownership beyond headline VA pricing.

This approach works well when vendors have tested their UPS system with common computers so that the user can select from a table that shows model and backup time. This approach does not work well when choosing a UPS system for demanding applications that involve cyclical loads such as starting electric induction motors. These motors are often used in air conditioners, conveyor belts and for gate control. For these scenarios, following tips for selecting a UPS system helps ensure adequate surge handling and motor-start margin.

Applications that require extended backup time also places additional demands on a UPS system. It is a little bit like automobile brakes. The average driver is happy as long as the car stops. Brakes basically convert kinetic energy to heat. The average car buyer does not care about rotor and caliper size and has never experienced brake fade. If the car is taken to the track and driven hard, it won’t take long before the brakes fail from overheating. Few cars are designed with brakes that can take such abuse. It really doesn’t matter to most people, so most cars have small brakes that are not up to rigorous performance standards. UPS cases are opposite because these systems are called upon to start motors, but comparable, due to high currents and the heat that is generated. When runtime is extended and currents rise, understanding UPS risks helps avoid thermal stress and premature failure.

Power Factor (also known as displacement power factor) is the cosine of the phase angle φ between the current and voltage sinusoidal waveforms. The power in a circuit that is transformed from electric to non-electric energy is called real power. The portion of power that is the result of stored energy, and which returns to the source over a full line cycle, is known as reactive power. Apparent Power Factor (also known as distortion power factor) is real power in watts (W) divided by the product of Vrms x Irms and is typical of the current drawn by a switchmode power supply that is not power factor corrected. The typical apparent power factor for such a power supply is 0.6 to 0.7. Apparent power factor is neither leading nor lagging, as there is no phase angle to speak of. If these terms are unfamiliar, reviewing what is a UPS system can help connect power factor concepts to real equipment behavior.

The UPS industry rates most products in VA which does not include the effects of harmonic current). A hypothetical UPS model might be called XX-1000 leading the prospective customer to assume that the UPS system could provide 1kVA of apparent power to a critical load. Studying the specifications reveals that the unit is capable of providing only 0.7kW of real power. The typical specification does not state power factor or maximum continuous current, nor does it allow for harmonic distortion. Not knowing load power factor or maximum current the user will not know for sure if the unit can operate at 1kVA. We will here argue for a more sensible industry specification for the discerning customer. Accordingly, a careful read of any UPS power supply specification should verify kW rating, maximum continuous current, and distortion limits to avoid misapplication.

Consider a user with an application that requires 1kVA of apparent power at an apparent power factor of 0.7 which is typical for computer loads. In such cases, confirming that the chosen UPS uninterruptible power supply can deliver the required kW at the actual load power factor will prevent nuisance trips.

Since the UPS system is only rated for 0.7kW, it would overheat fairly quickly as its inverter and inverter transformer are not rated to handle more than 0.7kW. This would not be a problem if the UPS system is designed with internal batteries to provide backup power for 10 to 20 minutes. It becomes a major problem if the customer connects and external battery bank to increase the backup time to several hours. This is often the case with special applications such as security and wireless systems. Why does the UPS industry use the obviously misleading VA specification (sometimes called computer VA). This practice originated in the 80s, as a now defunct company attempted to gain competitive advantage. It didn’t take long for the rest of the industry to follow. For extended-backup deployments, selecting an uninterruptible power supply with an honest watt rating and ample thermal headroom is essential for reliability.

HEATER

10kVA heater is a resistive load with a power factor of 1. Real power is 1kVA x 1 = 1kW and no reactive current is returned to the inverter, so the UPS system is unable to supply the load as it exceeds its rating by 0.3kW

ELECTRIC MOTOR

1kVA electric motor is a resistive/inductive load with a power factor of 0.8. Real power is 1kVA x 0.8 = 0.8kW with 0.6kVAR reactive power returned to the inverter, so the UPS system is unable to carry the load.

COMPUTER

1kVA computer is a rectifier/capacitor, non-linear load with a power factor of 0.7. Real power is 1kVA x 0.7 = 0.7kW with a 7.14kVAR of harmonic distortion current returned to the inverter. The above three cases clearly demonstrate the inadequacy of the VA-rating system. It is obvious that all of the above three cases would require a 1kW UPS system. This leads to the inescapable conclusion that it would be much better to rate UPS products in watts (W) instead of volt-ampere (VA).

From: Power Quality, Grounding & UPS Handbook, Vol 12, The Electricity Forum

Electrical Generators and UPS Channel

Uninterruptible Power Supply

Uninterruptible power supply (UPS) delivers battery backup, surge protection, voltage regulation, and power conditioning to keep servers, networks, and critical equipment running during outages, with online and line-interactive inverter designs.

What Is an Uninterruptible Power Supply (UPS)?

An Uninterruptible power supply delivers battery backup, surge protection, and voltage regulation to prevent downtime.

✅ Protects servers and networking gear from power loss

✅ Provides AVR for brownouts, sags, and surges

✅ Offers online or line-interactive inverter topologies

An uninterruptible power supply is an essential component of modern life, providing emergency backup, electrical protection, and voltage regulation for a wide range of applications. From safeguarding sensitive equipment like single-phase networking devices and preventing data loss to ensuring the smooth operation of life-saving devices, UPS systems play a crucial role in maintaining the reliability of electrical supply. By understanding the different types of UPS systems, their features, and their applications, one can make an informed decision when selecting the right UPS system for their specific needs. For a concise primer, the basics of UPS systems explain core concepts for new buyers.

A UPS system offers several benefits beyond providing backup during an outage. One of its essential functions is power protection, ensuring that electrical equipment remains safe from surges, voltage fluctuations, and other electricity-related issues. Surge protection plays a critical role in this aspect by safeguarding connected devices from sudden voltage spikes, which could cause irreversible damage. These protective roles are described in the context of a UPS power supply and how it stabilizes connected loads.

Voltage regulation is another vital aspect of uninterruptible power supplies. It helps maintain a constant voltage level for the connected equipment, especially during voltage fluctuations. This feature is essential for the smooth operation of sensitive equipment like computers, networking equipment, and medical devices.

UPS systems come in various types, such as single-phase and three-phase, based on the electrical load they can handle. The most common types are line-interactive, double conversion, and standby. Line-interactive UPS systems adjust the input voltage with the help of an autotransformer, while double conversion systems convert the input AC power to DC and then back to AC, providing a pure sine wave output. Standby UPS systems, on the other hand, only switch to battery during an outage. A helpful overview of uninterruptible power supply architectures clarifies how these modes differ in practice.

The heart of any UPS system is its battery backup, which provides emergency supply when the main source fails. These batteries store electrical energy and release it during outages or fluctuations. The battery's run time is a crucial factor to consider when selecting a UPS, as it determines how long the connected devices can continue to operate on backup supply. For planning runtime, this battery backup guide outlines sizing and replacement intervals.

Another aspect to consider when selecting a UPS system is the volt-ampere (VA) rating, which indicates the maximum electrical load the UPS can handle. It is essential to choose a UPS with a VA rating that matches the electricity requirements of the equipment it will protect. A detailed checklist in the UPS selection guide helps match VA and wattage to your load.

Uninterruptible power supplies are indispensable for a wide range of applications, from residential use to large-scale industrial setups. For example, in homes, a UPS can provide backup supply to essential appliances and devices during an outage, ensuring safety and comfort. In businesses, UPS systems protect sensitive equipment like servers and networking devices from power-related damage, preventing data loss and ensuring business continuity.

In mission-critical facilities like hospitals, uninterruptible power supplies play a vital role in providing emergency supply to life-saving equipment and maintaining essential operations during failures. Similarly, UPS systems are critical in data centers, where they protect against data loss and downtime caused by disruptions.

Surge protectors are often used in conjunction with UPS systems to provide an additional layer of protection. While a UPS safeguards against outages and voltage fluctuations, surge protectors protect connected devices from voltage spikes caused by lightning strikes or other electrical disturbances. It is also important to understand potential hazards, and this review of UPS risks explains common pitfalls and mitigation steps.

To ensure optimal performance, it is essential to select the right UPS system for your specific needs. Factors to consider include the type of equipment you need to protect, the required run time, and the appropriate VA rating. Additionally, it is essential to keep in mind that some devices, like sensitive equipment and devices with motors, may require a UPS with a pure sine wave output.

Regular maintenance is crucial for the longevity and performance of a UPS system. This includes periodically checking and replacing batteries, as well as monitoring the overall health of the system. Proper maintenance ensures that your uninterruptible power supply remains ready to provide backup power and protection when needed.

What are the different types of UPS systems, and how do they differ in functionality?

There are three main types of UPS systems:

Standby (offline) UPS: This type of UPS remains idle until a disruption occurs. When the main supply fails, it switches to battery to provide backup. Standby UPS systems are the most basic and cost-effective option, suitable for smaller applications like home computers.
Line-interactive UPS: This type of UPS actively regulates voltage by using a built-in transformer that adjusts input voltage to maintain a consistent output voltage. When am electrical outage occurs, it switches to battery supply. Line-interactive UPS systems are suitable for small businesses and office environments, providing protection against voltage fluctuations and outages.
Online (double-conversion) UPS: This type of UPS continuously converts incoming AC to DC and then back to AC, providing a pure sine wave output. It offers the highest level of electrical protection, isolating connected equipment from power disturbances. Online UPS systems are ideal for mission-critical applications, such as data centers and medical facilities, where consistent and clean power is essential.

How do I choose the right UPS system for my specific needs and equipment?

To choose the right UPS system, consider the following factors:

Application: Determine whether you need a UPS for home, office, or industrial use, and choose the appropriate type (standby, line-interactive, or online) accordingly.
Power requirements: Calculate the total electricity consumption of your equipment, and select a UPS with a sufficient capacity (measured in volt-amperes or watts) to handle the load.
Runtime: Determine how long you need the UPS to provide backup electricity in the event of an outage, and choose a system with a suitable battery capacity.
Voltage regulation and surge protection: Ensure the UPS provides the necessary level of voltage regulation and surge protection for your sensitive equipment.

What factors should I consider when determining the appropriate size and capacity of a UPS system?

Consider the following factors:

Power consumption: Calculate the total electricity consumption of the connected equipment (in watts or volt-amperes).
Runtime: Determine the desired runtime during an outage.
Expansion: Consider any potential future equipment additions that may increase electricity requirements.
Efficiency and redundancy: Account for UPS efficiency and, if needed, additional capacity for redundancy.

For organizations focused on lowering energy and cooling costs, a high efficiency UPS system can deliver meaningful savings without sacrificing protection.

How can a UPS system help protect my sensitive electronic equipment from electricity issues like power surges, outages, and voltage fluctuations?

A UPS system provides protection against electricity issues by:

Supplying backup electricity during outages, preventing data loss and equipment shutdown.
Regulating voltage to maintain a consistent output, protecting equipment from voltage fluctuations.
Providing surge protection to shield connected devices from voltage spikes that can cause damage.

What is the importance of regular maintenance and battery replacement for UPS systems?

Regular maintenance and battery power replacement are essential for:
Ensuring optimal performance and efficiency of the UPS system.
Prolonging the lifespan of the UPS and preventing premature failure.
Maintaining consistent backup electricity availability during outages.
Ensuring the safety and reliability of the UPS system and connected equipment.

How can a UPS system benefit various industries and applications, such as data centers, healthcare facilities, and residential use?

Data centers: UPS protects against data loss and downtime, ensuring business continuity and safeguarding critical IT infrastructure.
Healthcare facilities: UPS provides emergency electricity to life-saving equipment and essential systems, maintaining patient safety and care during electricity disruptions.
Residential use: UPS protects home electronics from electricity disturbances and provide backup power during outages, ensuring safety, comfort, and the continued operation of essential devices.

Electrical Generators and UPS Channel

Understanding Your UPS Power Supply - Uninterruptible Electricity

UPS power supply ensures uninterruptible power, voltage regulation, and surge protection with battery backup, inverter, and AVR, delivering clean sine-wave output for servers, networking gear, and industrial controls during outages and brownouts.

What Is a UPS Power Supply?

A backup system delivering regulated AC via inverter and ATS, keeping critical loads online during outages.

✅ Types: offline, line-interactive, double-conversion

✅ Features: AVR, surge suppression, pure sine wave

✅ Metrics: VA rating, runtime, transfer time, THD

WHAT IS A UPS POWER SUPPLY?

An Uninterruptible Power Supply (UPS) System is a device that supplies battery backup power to computers and peripherals during short power outages, and allows systems to safely shutdown during prolonged blackouts. UPS systems also correct brownouts and overvoltages, stop damaging power surges and filter disruptive line noise. An Uninterruptible Power Supply system sits between a power supply (e.g. a wall outlet) and a device (e.g. a computer) to prevent undesired features of the power source (outages, sags, surges, bad harmonics, etc.) from the supply from adversely affecting the performance of the device. For a deeper primer, consult what a UPS system entails to see how architectures differ.

WHAT CAUSES POWER PROBLEMS?

Despite advances in technology, power grids across the country are struggling to supply reliable power to homes and businesses. The increasing occurrence of large natural disasters such as Hurricane Katrina, along with the growing demand for electricity, have put a significant strain on power grids and an increase in damaging power problems. If your home office or business has ever been disrupted by a power problem, it’s not surprising. IBM estimates that 120 power problems hit the typical computer in a month—that works out to four per day! As a result, computer systems and electronics are under siege by more frequent blackouts, brownouts, overvoltages, surges and other power anomalies. Thanks to the aging of the nation’s power-producing infrastructure, these power problems are likely to become more and more common in the coming years. Local sources can also generate blackouts, brownouts, overvoltages and surges. For example, if your neighbor starts up an electrical motor or the office on the floor below you blows a fuse, a blackout, brownout, overvoltage or surge could result. Line noise is typically generated by turning on other power-drawing devices connected to the same electrical system. Turning on florescent lights, laser printers or appliances, working near a radio station, using a power generator or simply working during a lightning storm can all introduce line noise into connected equipment. Ever notice the “snow” on your TV when you use a blender or a hair dryer? That’s line noise being sent back into your electrical system and into your TV. To understand how these disturbances are measured and mitigated, review UPS fundamentals for context on sizing and topology.

Visit Our UPS System Training Page

WHAT ARE THE EFFECTS OF POWER PROBLEMS?

Blackouts, brownouts, power surges and line noise can result in computer system downtime or lockups, data loss, lost productivity, audio static, video snow, slow electronic degradation and ultimately catastrophic equipment damage. Additionally, organizations should be aware of UPS risks so mitigation plans cover maintenance, ventilation, and load management.

HOW DOES A UPS POWER SUPPLY WORK TO PROTECT AGAINST POWER PROBLEMS?

An Uninterruptible Power Supply System provides comprehensive protection against all power problems. To further understand how UPS Systems protect against power problems, consider the different types of UPS: A concise overview of modes and components is outlined in this Uninterruptible Power Supply reference for quick comparison.

STANDBY UPS POWER SUPPLY

Power is fed through surge and noise suppression circuitry and on to your equipment. Meanwhile, a battery charger keeps an internal battery topped off and ready for use. During a blackout, brownout or overvoltage, an inverter converts battery power into a simulated sine wave output. When power returns, the Uninterruptible Power Supply switches back to AC power and the battery is recharged. Sensing of a low-voltage situation and switching to battery power happens so quickly that your equipment continues to operate flawlessly.

LINE-INTERACTIVE UPS POWER SUPPLY

Power is fed through surge and noise suppression circuitry. Then built-in line conditioning circuitry regulates high or low voltages back to normal levels, and sends clean power on to your equipment, without using battery power. Meanwhile, a battery charger keeps an internal battery topped off and ready for use. During a blackout, an inverter switches on and converts battery power into a simulated sine wave output. When power returns, the inverter switches off and the battery is recharged. Because all switching happens within a few milliseconds, your equipment is unaffected.

ON-LINE UPS SYSTEMS

This is the highest level of battery backup protection available. Power is first broken down and then perfectly reconstructed by the inverter, which is “on-line” 100% of the time. There is absolutely no transfer switching time. This process completely eliminates incoming surge and line noise, adjusts high or low voltages, and produces perfect sine wave power. When energy costs matter, explore high-efficiency UPS strategies that reduce heat and operating expense.

IMPORTANT UPS POWER SUPPLY FEATURES

There are a number of other factors important to UPS users beyond its standby, line-interactive or on-line design. Auto shutdown, battery runtime, number of outlets and phone line suppression could be critical factors in choosing a system for a particular application. When evaluating these attributes, consult tips for selecting a UPS to match load, runtime, and management needs.

UNATTENDED SHUTDOWN RELATED FEATURES:

Monitoring Ports (Standard vs. Smart Monitoring) — Many Uninterruptible Power Supply supplies can “talk” to a connected device and instruct it to shut down when power fails. Models with a monitoring port have this ability. Tripp Lite offers UPS products with two types of monitoring ports, Standard and Smart. Standard Port (USB or DB9) — Able to send basic signals regarding “ON BATTERY”, “LOW BATTERY” and “POWER RESTORED” conditions. Smart “Enhanced” Monitoring Port (USB or DB9) — Same as standard interface with additional data regarding voltage, temperature, load level, and more can be transmitted to the connected computer. Many of the larger Smart products also have multiple monitoring ports so that a few connected computers or servers can be automatically shut down in the event of a power failure. This feature is especially valuable in data centers, computer rooms, and in cases where a single UPS will support several servers or workstations. Free Monitoring Software — Many of the models that include a monitoring port also support free PowerAlert UPS monitoring and shutdown software via download. It interprets the signals coming from the DB9 monitoring port and instructs the UPS to take the appropriate action. When the Uninterruptible Power Supply transmits a “power failure” message, the UPS waits a pre-configured period of time. If power isn’t restored by the end of the “wait” time, PowerAlert saves all data and shuts down the connected computer or server so that no data is lost.

RUNTIME RELATED FEATURES:

Expandable Battery Runtime — Most Uninterruptible Power Supply systems for computer use are sized to run for about 5-10 minutes at full load. Certain applications, such as telephone and critical networking systems, often require much longer battery runtimes (from 30 minutes to over 8 hours). Fax Modem/Surge-Only Outlets — Most home and home office PCs are equipped with a modem and several peripherals. Generally UPS protection is required for a computer and monitor only and all remaining items, like printers, scanners and other accessories, are connected to a separate surge suppression strip. Modem lines connecting to computers should also be protected with a data line surge suppressor. For planning purposes, see how long battery backups typically last across common sizes and conditions.

TYPICAL UPS POWER SUPPLY APPLICATIONS

UPS power supplies are designed to protect computers and all electronics from damaging blackouts, brownouts, over voltages, surges and line noise.

Electrical Generators and UPS Channel

What Size Emergency Generator Do I Need?

You need an emergency generator sized to your total wattage needs. Smaller units, ranging from 5 to 7 kW, cover essentials such as lights, refrigerators, and sump pumps, while units with 20–22 kW provide reliable whole-home backup, including HVAC systems.

What Size Emergency Generator Do I Need?

Refers to the process of calculating backup power capacity to match the energy demands of a household or business during outages.

✅ Determines generator size based on watts, circuits, and load

✅ Ensures appliances, HVAC, and lighting operate safely

✅ Prevents underpowered or oversized generator selection

Emergency Generator Standby Power Training

Power Quality Analysis Training

Request a Free Emergency Generator Training Quotation

The first step in choosing a generator is calculating your total wattage requirements. Appliances and devices draw two types of power: running wattage, which keeps the equipment operating, and starting wattage, sometimes referred to as surge watts, which is required during startup. Motors, pumps, and compressors often demand two to three times their running watts to start. Identifying the highest starting load is critical to prevent overloading your generator. When considering emergency backup generator options, it is important to compare capacity, fuel type, and wattage requirements to ensure your unit can handle both essential and whole-home loads.

Running watts cover steady-state demand, while starting watts account for those momentary peaks. For example, a refrigerator might require 700 running watts but 2,200 starting watts. If you plan to run multiple appliances simultaneously, your generator must be sized to meet the total running watts plus the highest single starting wattage. Understanding the emergency power supply options available helps homeowners decide whether a portable, inverter, or standby generator best matches their outage risks.

Essential vs Whole-Home Backup

Many homeowners must choose between powering only essential appliances and covering the entire house. Essential circuits usually include lighting, refrigerators, sump pumps, medical devices, and communication equipment. A portable generator rated between 5,000 and 7,500 watts usually provides adequate backup power for these needs. For homes and facilities with sensitive electronics, pairing a generator with a battery backup system can extend runtime and protect against short interruptions.

For those seeking seamless operation during power outages, a home standby generator is often the most suitable solution. Whole-home units are permanently installed, connected through an automatic transfer switch, and can power air conditioners, electric stoves, and central heating systems. House generators in the 18- to 22-kW range are commonly used for whole-home backup, ensuring that air conditioning units and HVAC systems remain operational. Learning how does a generator work provides useful insight into why surge watts and starting loads play such an important role in choosing the right size.

Types of Emergency Generators

Different types of generators are available for both residential and commercial applications. Portable generators are mobile and fueled by gasoline or propane, offering versatility during short-term outages. Inverter generators deliver cleaner power for sensitive electronics, operate quietly, and can be paralleled for more capacity. Home standby generators are fixed installations that run on natural gas or propane, providing automatic protection without manual intervention.

When choosing a generator, consider whether you need portability, quiet operation, or a permanent, automated solution. Powerful generators may be ideal for critical facilities, while inverter generators are suitable for households prioritizing fuel efficiency and reduced noise. Exploring the electrical generators and UPS channel gives a broader view of technologies, ratings, and selection tips that can guide your generator sizing decision.

Fuel Considerations

Fuel type influences convenience, runtime, and maintenance. Portable units typically run on gasoline, though dual-fuel models also accept propane. Home standby generators commonly use natural gas supplied by a utility line or propane stored on-site. Natural gas provides an uninterrupted fuel supply and eliminates storage issues, but requires a sufficient supply line. Propane offers longer storage life and flexibility.

Air Conditioning and High-Demand Loads

Air conditioning units are often the deciding factor when choosing the right size generator. Central systems have compressors that require very high starting wattage. A 3-ton air conditioner can easily exceed 6,000 surge watts at startup. If cooling is optional, smaller window units may lower demand and allow downsizing. Carefully assessing the highest starting load ensures the generator can handle surge watts without stalling.

Choosing the Right Size Generator

To size a unit accurately, follow this process:

List all appliances you want powered during outages.
Record their running wattage.
Identify the appliance with the highest starting wattage.
Add total running watts plus the single highest starting wattage.
Select a generator that exceeds this figure, leaving a 20 percent safety margin.

This approach avoids undersizing, which risks tripping breakers, and oversizing, which increases cost and reduces efficiency. For critical applications such as data centers, designing data center UPS infrastructure demonstrates how generators and UPS systems work together to deliver reliable power continuity.

Emergency Generator Sizing Checklist

Step	Action	Explanation
1	Identify all appliances and systems you want powered during an outage.	Start with essentials such as lights, refrigerator, sump pump, Wi-Fi, and medical devices.
2	Write down the running wattage for each device.	Check the appliance label or manual for the continuous power required.
3	Find the starting wattage of appliances with motors or compressors.	Items like an air conditioning unit, refrigerator, or pump need extra surge watts to start.
4	Add total running watts to the highest single starting wattage.	This combined total represents your minimum generator requirement.
5	Compare this number to generator ratings in running watts and surge watts.	Ensure the unit’s running capacity and surge rating both meet or exceed your needs.
6	Decide between essential-only coverage or whole-home backup power.	Smaller portable units cover essentials; home standby generators cover entire houses.
7	Consider fuel type: gasoline, propane, or natural gas.	Each has pros and cons for cost, storage, runtime, and convenience.
8	Choose from types of generators: portable, inverter, or standby.	Portable for flexibility, inverter for quiet, clean power, and standby for automatic operation.
9	Allow a safety margin of 20 percent above your calculated wattage needs.	Prevents overloads and ensures smoother operation during peak demand.
10	Plan for the installation, safe placement, and maintenance of the transfer switch.	A transfer switch prevents backfeeding; maintenance ensures long-term reliability.

Practical Scenarios

An essential-only setup might include lights, a refrigerator, a sump pump, and a small air conditioning unit. Combined running wattage may reach 3,500 watts, with starting surges pushing requirements to 6,000 watts. In this case, portable generators or paired inverter generators can suffice.

A whole-home backup scenario, including a central air conditioner, electric water heater, and cooking appliances, could demand 18–22 kW. Here, a home standby generator fueled by natural gas is the most suitable option.

Maintenance and Reliability

Even the most powerful generators require maintenance. Portable models need regular oil changes, fuel stabilization, and safe storage. Home standby systems should be exercised monthly and serviced annually. Ensuring transfer switches are tested and circuits are balanced guarantees reliable performance when power outages strike.

The question of what size emergency generator I need is answered by calculating wattage requirements, balancing running watts with surge watts, and factoring in the highest starting load. Smaller portable units provide backup power for essential appliances, while whole-home standby systems fueled by natural gas or propane ensure uninterrupted comfort, including the operation of air conditioners and HVAC systems. By carefully selecting a generator, considering the fuel type, and planning for regular maintenance, you can achieve reliable protection against outages while avoiding the pitfalls of underpowered or oversized equipment.

Frequently Asked Questions

How do I size a generator for an air conditioner?

To size a generator for just your air conditioning unit, check the unit’s starting watts and running watts on the nameplate. Add at least 20 percent for surge protection. A central air conditioner usually requires a larger home standby generator, while a window unit may be supported by a portable or inverter generator.

What are surge, peak, and starting watts?

Surge watts, peak watts, and starting watts all describe the brief power spike needed when a motor-driven appliance starts. They are higher than running watts and critical for choosing the right size generator. If ignored, the generator can stall or overload.

Can a portable generator power my whole home?

A portable generator can power an entire home only if it has sufficient capacity and is connected to the home's electrical system through a transfer switch. Without this, backfeeding into utility lines is dangerous. For whole-home backup, most homeowners rely on a permanently installed standby generator.

Is natural gas better than propane for standby units?

Natural gas is convenient because it provides an unlimited supply and eliminates the need for storage, but it relies on an active utility line. Propane is stored on-site, lasts longer in storage, and offers flexibility during utility disruptions. The best choice depends on availability and risk of outages.

Generators and UPS Channel

Hydrogen Detection System in UPS Battery Rooms

Hydrogen detection systems safeguard UPS battery rooms, generator facilities, and energy storage batteries by utilizing gas sensors for hydrogen leak detection, activating ventilation controls, and preventing fires, explosions, or equipment damage.

What is a Hydrogen Detection System?

A hydrogen detection system is a safety solution that continuously monitors gas levels in UPS battery rooms, generator facilities, and energy storage sites to prevent the buildup of hydrogen and protect people and equipment.

✅ Provides hydrogen leak detection with sensitive gas sensors

✅ Triggers alarms and ventilation control for explosion prevention

✅ Ensures compliance with NFPA, IEEE, and OSHA safety standards

Hydrogen detection systems are crucial in areas where large banks of lead-acid batteries provide backup power, including generator rooms, UPS systems, and mission-critical facilities. During charging cycles, especially boost or equalize charging, batteries release hydrogen gas. Because hydrogen is colourless, odourless, lighter than air, and flammable at just 4% concentration, it can silently accumulate under ceilings or in poorly ventilated areas. Even small leaks, if undetected, can create explosive conditions. Hydrogen detection systems are often paired with battery backup solutions to ensure that power reliability does not create hidden gas risks.

UPS System Training

Emergency Generators and Standby Power Training

Request a Free Training Quotation

Reliable hydrogen detection prevents this risk by providing real-time monitoring, triggering alarms, and activating ventilation systems before hazardous gas levels are reached. For facilities that depend on uninterrupted power—hospitals, data centers, airports, and industrial plants—these systems are not optional. They are a frontline defense against one of the most underestimated hazards in electrical infrastructure. Facilities using emergency backup generators also benefit from gas monitoring, since charging and standby batteries can release hydrogen in confined spaces.

How Detection Systems Work

A hydrogen detection system functions as a network of sensors, alarms, and ventilation controls. The sensors measure gas concentration in the air and alert operators when thresholds are exceeded. Most modern systems are designed to integrate seamlessly into building safety systems, automatically starting fans to disperse accumulated gas while notifying personnel of the hazard.

Several sensor technologies are available, each suited to different environments:

Electrochemical sensors – Highly sensitive to low concentrations, making them ideal for UPS battery rooms where precision is crucial.
Catalytic bead sensors – Rugged and reliable, often used in industrial generator facilities where durability matters most.
Metal oxide sensors – Robust and cost-effective, appropriate for continuous monitoring in large spaces.
Optical and thermal conductivity sensors – Specialized solutions that offer high sensitivity but at higher cost.

By combining various technologies in both fixed and portable formats, facilities can create a layered protection system that detects hydrogen early and ensures safe operating conditions.

When designing data center UPS infrastructure, hydrogen monitoring is a critical part of compliance and safety planning.

Comparison of Hydrogen Detection Technologies

Sensor Type	Sensitivity & Accuracy	Typical Applications	Pros & Cons
Electrochemical	Detects very low concentrations (ppm range)	UPS battery rooms, small generator rooms	Pros: High accuracy, fast response, good for compliance. Cons: Requires calibration every 6–12 months.
Catalytic Bead	Detects % volume concentrations of H₂	Rugged industrial generator facilities	Pros: Durable, reliable, long service life. Cons: Sensitive to poisoning, recalibration needed every 3–6 months.
Metal Oxide	Moderate sensitivity, continuous monitoring	General room coverage, cost-sensitive sites	Pros: Inexpensive, robust, easy to integrate. Cons: Less precise at very low concentrations.
Optical / IR	High sensitivity, fast response	High-risk or research facilities	Pros: Very accurate, can monitor remotely. Cons: Higher cost, complex installation.
Portable Units	Varies by sensor inside	Mobile inspections, maintenance checks	Pros: Flexible, immediate safety checks. Cons: Battery-powered, requires manual use.

Applications in Mission-Critical Facilities

Hydrogen monitoring plays a key role in protecting infrastructure across multiple sectors. In hospitals, it ensures the uninterrupted operation of intensive care units and surgical equipment. Data centers rely on it to prevent costly outages and equipment damage. Airports and transit hubs utilize it to maintain security and control systems online, while manufacturing plants rely on it to safeguard continuous production processes.

In each of these environments, battery rooms are often enclosed, poorly ventilated, and hidden from view—conditions that make hydrogen buildup especially dangerous. Installing detection systems in these facilities is both a safety requirement and an operational safeguard. Integrating hydrogen sensors into an uninterruptible power supply ensures that UPS systems operate safely during extended outages.

Codes, Standards, and Compliance

The importance of hydrogen detection is underscored by national and international safety standards. These documents set clear expectations for battery room safety:

NFPA 70 (National Electrical Code): Governs electrical safety for battery installations.
NFPA 110: Covers emergency and standby power systems.
NFPA 1 and NFPA 2 (Hydrogen Technologies Code): Limit hydrogen accumulation to no more than 25% of the lower flammable limit (≈1% concentration).
IEEE 1187 and IEEE 1635 / ASHRAE Guidance: Provide technical recommendations for ventilation and monitoring in battery rooms.
OSHA regulations: Require employers to protect workers from hazardous atmospheres.

Following these standards is not simply a matter of compliance—it reduces liability, protects lives, and ensures operational resilience.

Best Practices for Detector Placement

Hydrogen’s physical properties dictate how detection systems should be designed. Because the gas rises quickly, detectors should be installed near ceilings and above battery racks. Large rooms typically require multiple sensors to ensure full coverage. Additionally, detectors should be placed near doors, vents, and corners where air movement is minimal. In generator rooms, sensors should also be positioned near battery racks, control panels, and any adjacent spaces where gas could migrate. Operators should understand UPS risks, including hydrogen buildup, to avoid accidents and downtime.

Detection is most effective when paired with engineered ventilation. The most reliable systems use dual thresholds: the first activates mechanical ventilation fans at low gas concentrations, while the second triggers alarms at higher levels to alert personnel. Ventilation should exhaust directly outdoors, not into other building spaces, and should remain functional during power outages by being connected to standby circuits. This ensures that hydrogen is dispersed at precisely the times it is most likely to accumulate.

Because hydrogen rises, detectors must be positioned where gas is most likely to accumulate. Placement, however, is not simply a matter of putting one device on the ceiling. In practice, facilities achieve reliable coverage by:

Installing detectors at the highest points, above racks or near ceilings.
Placing additional units near doors, vents, and corners where air circulation may be poor.
Using multiple detectors in larger battery rooms to cover the entire volume of space.

A thoughtful placement strategy ensures that hydrogen is detected early, before it can reach hazardous concentrations.

Selecting the Right Detector

Different facilities require different detection solutions. UPS battery rooms benefit from electrochemical sensors that can detect very low gas levels. Industrial generator facilities may prefer catalytic bead sensors, valued for their long service life and ability to withstand challenging conditions. Portable hydrogen detectors add flexibility, allowing technicians to check multiple rooms and verify fixed system readings. Many facilities utilize a combination of fixed and portable units to provide comprehensive coverage.

Integrating Ventilation with Detection

Detection alone is not enough. For safety, it must work hand-in-hand with engineered ventilation. The most effective setups use dual thresholds: the first, at a low concentration, activates mechanical ventilation fans to dilute the gas, while the second, slightly higher, triggers alarms to alert staff. Exhaust systems must discharge outdoors, not into other building spaces, and should be powered by backup circuits so they continue running during outages—the very time batteries are most likely to be charging heavily.

Maintenance and Training

Installing detectors is only the first step. For hydrogen detection to remain effective, systems must be properly maintained, and staff must receive regular training. Sensors require periodic calibration, with intervals ranging from a few months to a year depending on technology. Systems should be tested with certified test gases to confirm proper alarm function. Documentation of inspections and maintenance is essential for compliance and accountability.

Equally important is human readiness. Workers should be trained to recognize alarm conditions, know when to evacuate, and understand how to restart operations once a room is cleared. Facilities that pair reliable technology with well-prepared personnel are the safest in the long term.

Lessons from Real Incidents

Several hydrogen-related accidents in battery rooms serve as stark reminders of the risks. In one case, a data center experienced an explosion after detectors raised alarms for days, but ventilation fans were disabled for maintenance. In another case, improper placement resulted in hydrogen accumulating in areas beyond the sensors' reach. These events underscore the importance of both well-designed and consistently maintained detection systems. Technology alone is not enough—discipline in maintenance and adherence to safety protocols are equally vital.

Hydrogen detection systems in generator and UPS battery rooms provide essential protection against an invisible but serious hazard. By combining accurate sensors, thoughtful placement, integrated ventilation, and well-trained staff, facilities can prevent accidents, comply with safety standards, and protect both people and infrastructure. In environments where uninterrupted power is critical, hydrogen detection is not just a safeguard—it is a necessity. Ultimately, understanding what a UPS system is provides context for why hydrogen monitoring is crucial in backup power environments.