May. 26, 2025
In many industries, including health care, manufacturing, electrical contracting, higher education and corrections, reliable, high-quality transformers are essential for keeping operations running efficiently. Large facilities and industrial processes require substantial amounts of power, and they need dependable transformers to convert the energy coming from the power plant into a form they can use for their equipment and building utilities.
How do transformers help commercial and industrial facilities achieve these goals?
Transformers convert energy from the source to the power required by the load. To use their transformers effectively, businesses need to know how much power their particular transformers can give them. A transformer’s rating provides that information.
The transformer typically consists of two windings, a primary and secondary winding. Input power flows through the primary winding. The secondary winding then converts the power and sends it to the load through its input leads. A transformer’s rating, or size, is its power level in kilovolt-amperes.
When a piece of electrical equipment malfunctions, the transformer is often the culprit. In that case, you’ll probably need to replace your transformer, and when you do, you’ll need to select one with the correct kVA for your needs. If not, you run the risk of frying your valuable equipment.
How do you choose a transformer size? Fortunately, sizing your transformer is relatively simple. It involves using a straightforward formula to generate your kVA requirements from the current and voltage of your electrical load. In the guide to transformer kVA ratings below, we’ll explain in more detail how to calculate the required capacity kVA rating.
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When you’re figuring out kVA size, it’s helpful to have the terminology and abbreviations straight before you begin. You’ll sometimes see transformers, especially smaller ones, sized in units of VA. VA stands for volt-amperes. A transformer with a 100 VA rating, for instance, can handle 100 volts at one ampere (amp) of current.
The kVA unit represents kilovolt-amperes, or 1,000 volt-amperes. A transformer with a 1.0 kVA rating is the same as a transformer with a 1,000 VA rating and can handle 100 volts at 10 amps of current.
To determine your kVA size, you’ll need to make a series of calculations based on your electrical schematics.
The electrical load that connects to the secondary winding requires a particular input voltage, or load voltage. Let’s call that voltage V. You’ll need to know what this voltage is — you can find it by looking at the electrical schematic. We could say that an example load voltage V must be 150 volts.
You’ll then need to determine the particular current flow your electrical load requires. You can look at the electrical schematic to determine this number as well. If you can’t locate the required current flow, you can calculate it by dividing the input voltage by the input resistance. Let’s say the required load phase current, which we’ll call l, is 50 amperes.
Once you’ve located or calculated these two figures, you can use them to figure out the load’s power requirements depending on the type of transformer.
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A single-phase transformer uses a single-phase alternating current. It has two lines of alternating current (AC) power. Below are a few common types:
To calculate the kVA rating for a single-phase transformer, you’ll need to multiply the required input voltage (V) by the required current load in amperes (l) and then divide that number by 1,000:
For example, you would multiply 150 by 50 to get 7,500 and then divide that number by 1,000 to get 7.5 kVA.
A three-phase transformer can take one of a few different forms. It typically has three lines of power, where each line is out of phase with the other two by 120 degrees.
Compared with single-phase transformers, three-phase transformers come in similar types:
The calculation for a three-phase transformer kVA is a little different from the calculation for a single-phase kVA. Once you’ve multiplied your voltage and amperage, you’ll also need to multiply by a constant — 1.732, which is the square root of 3 truncated to three decimal places:
So if you’re working with a three-phase transformer, instead of multiplying the voltage by the amperage and dividing by 1,000 to get the kVA, you’ll multiply the voltage by the amperage by 1.732 and still divide by 1,000 to get the kVA.
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Starting a device generally requires more current than running it. To account for this additional current requirement, it’s often helpful to add a start factor into your calculations. A good rule of thumb is to multiply the voltage by the amperage and then multiply by an additional start factor of 125%. Dividing by a power factor of 0.8, of course, is the same thing as multiplying by 1.25.
However, if you start your transformer often — say more than once an hour — you may want a kVA even larger than your calculated size. And if you’re working with specialized loads, such as those found with motors or medical equipment, your kVA requirements may differ substantially. For specialized applications, you’ll probably want to consult a professional transformer company for advice on what kVA you need.
To convert the figure of a transformer from kilowatts to kilovolt-amperes, you’ll need to divide by 0.8, which represents the typical power factor of a load. Let’s say you know the transformer is operating at 7.5 kW. The equation would look like this:
In the example above, you’d divide 7.5 by 0.8 to get 9.375 kVA. When you’re choosing a transformer, though, you won’t find one rated 9.375 kVA. Most kVA ratings are whole numbers, and many, especially in the higher ranges, come in multiples of five or 10 — 15 kVA, 150 kVA, 1,000 kVA and so on. In most cases, you’ll want to select a transformer with a rating slightly higher than the kVA you calculated — in this case, probably 10 or 15 kVA.
You can also work backward and use the known kVA of a transformer to calculate the amperage you can use for three-phase transformers:
If your transformer is rated at 1.5 kVA, and you want to operate it at 25 volts, multiply 1.5 by 1,000 to get 1,500 and then divide 1,500 by 25 to get 60. Finally, divide 60 by the square root of 3 — which equals 1.732 — and you get 34.64 amperes. So, your transformer will allow you to run it with up to around 35 amperes of current.
If the idea of performing calculations when you need to figure out kVA seems daunting or unappealing, you can always turn to charts. Many manufacturers supply charts to make determining the correct kVA easier. If you use a chart, you’ll locate your system’s voltage and amperage in the rows and columns and then find the kVA listed where your chosen row and column intersect.
It’s easy to talk about transformer size calculations in the abstract and come up with an array of numbers. But what are standard sizes for transformers that you might purchase?
Standard transformer sizes refer to predefined and commonly available ratings of transformers that are on the market. These sizes are established by industry standards and provide a range of options to choose from. As a result, you can find a transformer that meets your specific needs without requiring custom manufacturing. Standard transformer sizes also facilitate compatibility and interchangeability, and allow for easy replacement of or adding to transformers in electrical systems without significant modifications.
Standard sizes cover a variety of transformer kVAs, from smaller systems used in residential applications to larger ones for industrial settings. Especially for commercial buildings, the most common sizes for transformers are the following:
When selecting a transformer, these standard sizes provide reliable and readily available solutions that have been tested and proven in various applications. For example, if you need a transformer size of 52.5 kVA to convert a system, you would select a 75 kVA transformer out of the available standard ratings since it has a better capacity than a 45 kVA transformer.
If you work with specialized loads where your kVA requirements fall outside available standard sizes, custom transformers can be designed and manufactured to suit your specific needs.
Sometimes transformers are rated in megavolt-amperes, or MVA, to indicate the bigger size and capacity of the system. In other words, it is typically used when the ratings of electrical systems and equipment exceed the kVA range.
MVA stands for megavolt-amperes, and one MVA is 1 million volt-amperes.
Like kVA, MVA is a unit used to measure the power capacity of large electrical systems and equipment. Since MVA represents the product of voltage and current on a very large scale, it is commonly used when dealing with high-power systems, such as:
Converting kVA to MVA is a straightforward process if you remember the difference between kVA vs. MVA:
Let’s say you have a power rating of 3,750 kVA and want to convert this measurement to MVA. Since there are 1,000 kVA in one MVA, you will divide the kVA value by 1,000 to convert it to MVA. In this example, the equation would look like this: 3,750 kVA / 1,000 = 3.75 MVA
Depending on the level of accuracy required, you can round the converted value to the desired decimal places.
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To calculate the MVA rating of a three-phase transformer, we’ll use the same numbers in the example that calculated the kVA size — the load voltage V is 150 volts and the load phase current I is 50 amperes.
In this example, it’s better to use the kVA rating to describe the transformer’s capacity rather than the MVA rating.
Before you can calculate the necessary kVA for your transformer, you’ll need to figure out your load voltage, which is the voltage required to operate the electrical load. To determine your load voltage, you can look at your electrical schematic.
Alternatively, you may have the kVA of your transformer and want to calculate the necessary voltage. In that case, you can adjust the equation we used above. Since you know kVA = V * l / 1,000, we can solve for V to get V = kVA * 1,000 / l.
So you’ll multiply your kVA rating by 1,000 and then divide by the amperage. If your transformer has a kVA rating of 75 and your amperage is 312.5, you’ll plug those numbers into the equation — 75 * 1,000 / 312.5 = 240 volts.
The primary and secondary circuits coil around the magnetic part of the transformer. A couple of different factors determine the secondary voltage — the number of turns in the coils and the voltage and current of the primary circuit.
You can calculate the voltage of the secondary circuit by using a ratio of the voltage drops through the primary and secondary circuits, along with the number of circuit coils around the magnetic part of the transformer. We’ll use the equation t1/t2 = V1/V2, where t1 is the number of turns in the primary circuit’s coil, t2 is the number of turns in the secondary circuit’s coil, V1 is the voltage drop in the primary circuit’s coil and V2 is the voltage drop in the secondary circuit’s coil.
Let’s say you have a transformer with 300 turns in its primary coil and 150 turns in its secondary coil. You also know that the voltage drop through the first coil is 10 volts. Plugging these numbers into the equation given above yields 300/150 = 10/t2, so you know t2, the voltage drop through the secondary coil, is 5 volts.
Remember that every transformer has a primary and secondary side. In many cases, you’ll want to calculate the primary voltage, which is the voltage the transformer receives from a power source.
You can determine that primary voltage by using the ratios of current and voltage from the transformer’s primary and secondary coils. Maybe you know your transformer has a current of 4 amps and a voltage drop of 10 volts through its secondary coil. You also know your transformer has a current of 6 amps through the primary coil. What should the voltage drop through the primary coil be?
Let i1 and i2 equal the currents through the two coils. You can use the formula i1/i2 = V2/V1. In this case, i1 is 6, i2 is 4, and V2 is 10, and if you plug those numbers into the formula, you get 6/4 = 10/V1. Solving for V1 gives you V1 = 10 * 4/6, so the voltage drop through the primary circuit should be 6.667 volts.
To see the benefits of quality, high-performing transformers in your business, partner with ELSCO Transformers. We provide a range of transformer services to keep your business operating smoothly, including transformer repairs, rebuilds, retrofits, rewinds and emergency replacements.
We also offer a few different types of brand-new medium voltage transformers, including dry-type, pad-mount, unit substation and station-type transformers. We’re also happy to develop custom-built transformers to meet your facility’s unique needs and specifications. We have years of experience supplying transformers for various industries, including electrical contractors, electrical supply houses, hospitals and medical clinics and manufacturing facilities, among many others.
A malfunctioning or broken-down transformer can lead to costly delays and make your business less profitable. Keep your operations running efficiently by staying on top of transformer repairs or getting a custom new system from ELSCO Transformers. Our essential staff members have over two decades of experience in the industry, and we parlay that extensive experience, knowledge and expertise into giving you reliable units that will run dependably and perform well for years.
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Everyone hates the 9-hour shutdown at homes because life is too uncomfortable without Television, mobile phones (no charger to keep it on), refrigerators, and air conditioners. Admit it! Electricity has become indispensable in this modern era and one cannot think of a world without it. Well, not anymore. We would never want to go back to the old days. We are happy with our new lives filled with modern inventions. However, electricity is not that modern but it has been years.
Talking about electricity in our everyday life, Transformers play a significant role in the transmission of electrical energy from the power plants (generation) to our doorstep (distribution). Transformers regulate electricity by either increasing or decreasing the alternating current within the electrical system.
With a wide variety of transformers available in the market, it is crucial to analyze and choose the right one that suits your requirements. The most widespread and commonly used transformers arePower transformers and Distribution transformers and they both have different applications and purposes.
Unlike distribution transformers where the transformers are always in energizing conditions, Power transformers are put into operation only when the load connected to it is to be operated. They are designed to handle high voltage inputs and can operate at more than 95% efficiency on full load whereas Distribution transformers will have high efficiency when operated at 50% to 70% load.
Power transformers have greater insulation property which results in increased cooling and also functions at low noise levels when compared to other transformers.
The expected life of power transformers is considered to be between 20 to 40 years.
When you have high voltage applications that require 100% efficiency at full loads and a constant power supply with the least fluctuations, it is the Power transformer you are looking for.
Power transformers have a wide range of applications across a multitude of residences, industries, power generation, and distribution stations, commercial spaces, reactors, auxiliary plants – to modify and regulate the power to a specific voltage level that is suitable for the given application.
Now that we know the features and applications of a Power transformer, let’s dive into our guide that states 5 things that you need to know before buying a power transformer.
First things First, before we look into our list, it is important to first gather some information about your voltage and power requirements. This can help you avoid mistakes related to voltage compatibility and wrong purchases.
There are several transformer manufacturing companies out there with a wide range of product options for different applications. Choosing the right one that matches your requirements can be a little daunting task. Here are few factors that will help you in the quest for your power transformer.
Transformers are rated according to the level of power that they can safely handle without overheating causing damage. It is simply the maximum power that the transformer can deliver. The power transformer rating is usually in kilovolt amperes (kVA) or megavolt amperes (MVA) which is stamped on the transformer nameplate.
Since a Power transformer can operate close to the maximum capacity, it is important to ensure that the power rating is high enough. If the transformer has to handle higher power than its actual power rating, it can produce overheating and damage. So, it is essential to calculate the maximum power that the transformer may have to handle after installing it and then getting the transformer with the next higher rating.
An ideal transformer will have no losses and therefore be 100% efficient. As we know, power transformers are expected to operate at more than 95% efficiency. This means that the losses from the transformers should be minimized as much as possible. Two major causes of losses are the iron core (iron loss) and the copper winding (copper loss). The maximum efficient point is where both the losses match.
Before making the purchase, ensure whether
The transformer tank provides the containment for the core and windings and the dielectric fluid or insulation oil. It must withstand the forces imposed on it during transport and operation. Power transformers are usually heavy and huge equipment, occupying a lot of space. They are also in constant exposure to the external surroundings and elements of nature.
The more durable and robust the tank is, the better the performance of the transformer is. You need to confirm beforehand that the tank is so manufactured with strong, corrosion-resistant, and leak-proof arrangements.
The Vector Group is a notation that provides details on the winding configurations (star/delta configurations) and the phase angle difference between the windings. Each group comprises of three methods of connection of high voltage and low voltage windings. Therefore, determining the vector group of the Power transformer before buying it is the key for the successful parallel operation of transformers in your network. Otherwise, it can cause circulating currents and other disturbances leading to unnecessary losses and decreased efficiency.
Last but not least, the quality of the transformer plays a vital role. Power transformers are expected to run incessantly 24*7 at their maximum load capacity and the components of the transformer are subject to heavy mechanical and electrical loads.
Thus, before making a transaction to buy a power transformer, you must communicate your needs clearly to the manufacturer and ensure that the transformer can endure heavy-load conditions without breaking down. Also, check if best designing solutions such as making use of continuous windings with minimal joints, better insulation, and other standard quality assurance practices were followed while manufacturing the transformer.
Keeping these points and your requirements in mind, you should pose the right questions to the power transformer manufacturer and see if the product really matches your needs before making the purchase. Other key specifications to look out for are – Input and load voltage, phase requirements, size/capacity, frequency of operations, impedance, protection, mount/spacing, and location requirements.
By choosing the right power transformer, you can increase the efficiency and the life of your application. Having a better understanding of your requirements with a little bit of accurate research to realize the complete monetary value of the product can help you make worthy purchase decisions.
Besides this, purchasing from a credible and reputed power transformer manufacturer like EVR Electricals guarantees a quality product that will last longer and will be reliable. You can also seek advice from the supplier to pick the right one to suit your application. A good manufacturer will also help you with installation and regular maintenance.
EVR Electricals is the leading power transformer manufacturers in Tamil Nadu. They build transformers using high-end technology, top-quality components, and trailblazing latest processes. Their sophisticated design of the products ensures sustainability and longevity without any service. The company also manufactures distribution transformers, Isolation transformers, Convertor/Invertor Transformers, Automatic voltage regulators, industrial refrigerators, etc.
Do you have any other points to add to help the readers understand better? Feel free to comment with your thoughts! Have a great day!
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