What is the difference between kW and kVa?
The primary difference between kW (kilowatt) and kVA (kilovolt-ampere) is the power factor. kW is the unit of real power and kVA is a unit of apparent power (or real power plus re-active power). The power factor, unless it is defined and known, is therefore an approximate value (typically 0.8), and the kVA value will always be higher than the value for kW.
In relation to industrial and commercial generators, kW is most commonly used when referring to generators in the United States, and a few other countries that use 60 Hz, while the majority of the rest of the world typically uses kVa as the primary value when referencing generator sets.
To expand on it a bit more, the kW rating is essentially the resulting power output a generator can supply based on the horsepower of an engine. kW is figured by the horsepower rating of the engine times .746. For example if you have a 500 horsepower engine it has a kW rating of 373. The kilovolt-amperes (kVa) are the generator end capacity. Generator sets are usually shown with both ratings. To determine the kW and kVa ratio the formula below is used.
0.8 (pf) x 625 (kVa) = 500 kW
What is a power factor?
The power factor (pf) is typically defined as the ratio between kilowatts (kW) and kilovolt amps (kVa) that is drawn from an electrical load, as was discussed in the question above in more detail. It is determined by the generators connected load. The pf on the nameplate of a generator relates the kVa to the kW rating (see formula above). Generators with higher power factors more efficiently transfer energy to the connected load, while generators with a lower power factor are not as efficient and result in increased power costs. The standard power factor for a three phase generator is .8.
What is the difference between standby, continuous, and prime power ratings?
Standby power generators are most often used in emergency situations, such as during a power outage. It is ideal for applications that have another reliable continuous power source like utility power. It’s recommend usage is most often only for the duration of a power outage and regular testing and maintenance.
Prime power ratings can be defined as having an “unlimited run time”, or essentially a generator that will be used as a primary power source and not just for standby or backup power. A prime power rated generator can supply power in a situation where there is no utility source, as is often the case in industrial applications like mining or oil & gas operations located in remote areas where the grid is not accessible.
Continuous power is similar to prime power but has a base load rating. It can supply power continuously to a constant load, but does not have the ability to handle overload conditions or work as well with variable loads. The main difference between a prime and continuous rating is that prime power gensets are set to have maximum power available at a variable load for an unlimited number of hours, and they generally include a 10% or so overload capability for short durations.
If I am interested in a generator that is not the voltage I need, can the voltage be changed?
Generator ends are designed to be either reconnectable or non-reconnectable. If a generator is listed as reconnectable the voltage can be changed, consequently if it is non-reconnectable the voltage is not changeable. 12-lead reconnectable generator ends can be changed between three and single phase voltages; however, keep in mind that a voltage change from three phase to single phase will decrease the power output of the machine. 10 lead reconnectable can converted to three phase voltages but not single phase.
What does an Automatic Transfer Switch do?
An automatic transfer switch (ATS) transfers power from a standard source, like utility, to emergency power, such as a generator, when the standard source fails. An ATS senses the power interruption on the line and in turn signals the engine panel to start. When the standard source is restored to normal power the ATS transfers power back to the standard source and shuts the generator down. Automatic Transfer Switches are often used in high availability environments such as data centers, manufacturing plans, telecommunication networks and so forth.
Can a generator I am looking at parallel with one I already own?
Generator sets can be paralleled for either redundancy or capacity requirements. Paralleling generators allows you to electrically join them to combine their power output. Paralleling identical generators will not be problematic but some extensive thought should go into the overall design based on the primary purpose of your system. If you are trying to parallel unlike generators the design and installation can be more complex and you must keep in mind the affects of engine configuration, generator design, and regulator design, just to name a few.
Can you convert a 60 Hz generator to 50 Hz?
In general, most commercial generators can be converted from 60 Hz to 50 Hz. The general rule of thumb is 60 Hz machines run at 1800 Rpm and 50 Hz generators run at 1500 Rpm. With most generators changing the frequency will only require turning down the rpm’s of the engine. In some cases, parts may have to be replaced or further modifications made. Larger machines or machines already set at low Rpm are different and should always be evaluated on a case by case basis. We prefer to have our experienced technicians look at each generator in detail in order to determine the feasibility and what all will be required.
How do I determine what size Generator I need?
Getting a generator that can handle all your power generation needs is one of the most critical aspects of the purchasing decision. Whether you are interested in prime or standby power, if your new generator can’t meet your specific requirements then it simply won’t be doing anyone any good because it can put undue stress on the unit.
What KVA size is needed given a known number of horsepower for my electric motors?
In general, multiply the total number of horsepower of your electric motors by 3.78. So if you have a 25 horsepower three phase motor, you will need 25 x 3.78 = 94.50 KVA to be able to start your electric motor direct on line.
Can I convert my three phase generator into single phase ?
Yes it can be done, but you end up with just 1/3 the output and the same fuel consumption. So a 100 kva three phase generator, when converted to single phase will become a 33 kva single phase. Your cost of fuel per kva would be three times more. So if your requirements are just for single phase, get a true single phase genset, not a converted one.
Can I use my three phase generator as three single phases ?
Yes it can be done. However, electrical power loads on each phase must be balanced so as not to give unneccesary strain on the engine. An unbalanced three phase genset will damage your genset leading to very expensive repairs.
Emergency/Standby Power for Businesses
As a business owner, an emergency standby generator provides an added level of insurance to keep your operation running smoothly without interruption.
Costs alone should not be the driving factor in purchasing an electric power genset. Another advantage to having a localized backup power supply is to provide a consistent power supply to your business. Generators can provide protection against voltage fluctuations in the power grid can protect sensitive computer and other capital equipment from unexpected failure. These expensive company assets require consistent power quality in order to function properly. Generators also allow for end users, not the power companies, to control and provide a consistent power supply to their equipment.
End users also benefit from the ability to hedge against highly volatile market conditions. When operating in a time-of-use based pricing situation this could prove to be a huge competitive advantage. During times of high power pricing, end users can switch the power source to their standby diesel or natural gas generator for more economical power.
Prime and Continuous Power Supplies
Prime and continuous power supplies are often used in remote or developing areas of the world where there is no utility service, where available service is very expensive or unreliable, or where customers just simply choose to self-generate their primary power supply.
Prime power is defined as a power supply that supplies power for 8-12 hours a day. This is typical for businesses such as remote mining operations that require a remote power supply during shifts. Continuous power supply refers to power that must be continually supplied throughout a 24 hour day. An example of this would be a desolate city in the remote parts of a country or continent that is not connected to an available power grid. Remote islands in the Pacific Ocean are a prime example of where power generators are used to provide continuous power for the residents of an island.
Electric power generators have a wide variety of uses throughout the world for individuals and businesses. They can provide many functions beyond just supplying backup power in case of emergencies. Prime and continuous power supplies are needed in remote areas of the world where the power grid does not extend to or where power from the grid is unreliable.
There are numerous reasons for individuals or businesses to own their own backup/standby, prime, or continuous power supply generator set(s). Generators provide an added level of insurance to your daily routine or business operations ensuring uninterrupted power supply (UPS). The inconvenience of a power outage is rarely noticed until you are the victim of an untimely power loss or disruption.