Load factor is an extremely useful calculated value that can help facility and energy managers spot data problems, metering problems, rate change opportunities, and mechanical electrical system control problems. By monitoring and optimizing load factor, managers can ensure better energy efficiency and cost control.
What is load factor? How is it calculated? And how is it used?
Simply stated, load factor is the ratio of highest actual kilowatt (kW) demand during the billing period to the maximum theoretical kilowatt hour (kWh) use, if demand remained constant for the entire billing period. The actual electricity use in kWh is what you see on your bill. The electricity demand (in kW) is your “peak load.” The load factor formula is:
Monthly kWh/(monthly peak KW Demand * days in billing period * 24 hours)
To calculate load factor, follow these simple steps:
Step 1: Find Monthly kWh
Identify the total electricity used during the billing period in kilowatt-hours (kWh). This is usually found on your utility bill.
Example: 40,000 kWh
Step 2: Identify Monthly Peak kW Demand
Find the peak demand (kW), which is the highest amount of electricity your facility required at any point during the month.
Example: 100 kW
Step 3: Determine the Billing Period Duration
Check the number of days in the billing period. Usually, it’s 30 days.
Example: 30 days
Step 4: Calculate Maximum Theoretical Use
Multiply the peak demand (kW) by the number of days in the billing period and then by 24 hours:
The load factor is 55.5%, meaning your facility used, on average, 55.5% of the maximum possible demand during the billing period. Understanding this metric helps optimize energy use and identify cost-saving opportunities.
What is the value in monitoring load factor?
First, let us consider situations where we might expect a very high load factor—where the percentage value is closer to 100 percent.
High load factor is only found in scenarios where a very steady load is present—where energy demand remains constant or nearly constant throughout the billing period. What types of structures or equipment might fit this profile? A data center might. So would a refrigerated warehouse, a supermarket, or an enclosed parking deck with lighting that is on for all hours of the day or night. In situations like these, the actual use is typically very close to the maximum theoretical use because everything is running all the time.
A high load factor profile is important because it might qualify the account/meter for a special low-cost rate. Utility companies appreciate high load factor meters because demand is predictable, which makes it easier for planning for power generation. If you discover a meter associated with a load factor over 80% or 90%, always check to see if the meter is on a rate schedule that will reward you for that.
But what if you notice a very high load factor in some other kind of building, such as an office building, school, retail store, restaurant, or hotel? You might think it’s a good opportunity to benefit from a high-load utility rate. However, the reality may be that the building is being managed inefficiently.
Remember that high load factor is associated with a very steady load, which means there is probably no nighttime or weekend setback for that building/meter. With effective nighttime or weekend setbacks in place, the facility would not be running at a steady load. Instead, the load would be lower at night and higher during the day. It would be higher during the work week, and generally lower on the weekends.
Should you observe a high load factor within a building type that is not commonly associated with higher load factors, your response should be: “Why is the load factor so high? Why aren’t we turning things off at night?” A high load factor is often a sign of building control problems but may also indicate billing or metering problems. Either way, there may be an opportunity for significant energy savings.
What if your load factor is over 100 percent?
A load factor above 100% means that the actual use was higher than the maximum theoretical demand for that meter, which is impossible. This scenario is an indication of a data problem. Always investigate if you discover a load factor reading greater than 100%.
What about the other side of the spectrum— low load factor?
What does it mean if the load factor is under 20 percent? It means that you have a very “spiky” load. Significant load is being generated but only for a short period of time, then that equipment turns off. What type of situations would fit this scenario?
An outdoor athletic field is a textbook example of sporadic but intense lighting needs. Another example might be a standby pump, an irrigation pump, or a stormwater ejector pump. This type of equipment operates in high gear, but only occasionally, and for short periods of time.
If you notice a low load factor associated with an office, store, restaurant, or a school, it may be a cause for concern. Inconsistent and widely varying loads are not normal for these facilities. A low load factor often indicates a data problem, meter problem, or billing problem. It may also indicate equipment that is oversized for the energy need.
The equipment may be generating a very heavy load but only for a short period of time. That scenario can also result in expensive long-term demand ratchet penalties. It’s good to know that, especially when it’s time to replace that equipment.
What’s a typical load factor?
A medium load factor—40% to 60%—would be typical for offices, restaurants, schools, and other building types that have nighttime and weekend setbacks. There might be some variation through the year, depending on HVAC needs, but that is what you should expect to see for those types of structures. A load factor report from your energy and utility management platform, like the one below from EnergyCAP, it’s easy to spot load factor problems.
Let’s take a closer look at some load factor examples, using more EnergyCAP charts. The first example is a meter associated with outdoor recreation.
Notice that for every monthly data point, the load factor is below 15%. Why might this be? The most likely answer is that most of the load is supplied for a significant electric lighting load, which is only required when the field is in use.
But why is the load factor higher in the winter than it is in the summer? This is because in the winter, the lights are on for more hours because there are more hours of darkness. The actual use, the numerator, is a larger number in the winter. It’s a low number when compared to the maximum theoretical demand, but it’s still a larger number than in the summer, when we see the same demand wattage, but for a shorter period of time because there are more hours of daylight.
This second graph represents the load factor of a data center.
The data center is averaging about 90% load factor—very constant throughout the year, as we might expect for a building of this type.
The next example is a public library. With the library, notice that the load factor is higher in the summer than it is in the winter. This happens to be a public library in Florida. A likely explanation is that, due to the threat of mold and mildew, library staff probably run the air conditioning nearly all the time in order to control humidity.
The last example is a typical office building.
The load factor is about 50 percent, with minor seasonal variation.
To learn more about identifying load factor issues and other ways to find energy cost savings, download our eBook, 20 Ways to Find Utility Bill Savings.
As you continue to optimize your facility’s energy usage, EnergyCAP’sUtility Management Software can help you track energy performance in real-time, identify inefficiencies, and generate actionable insights for improving energy efficiency. With EnergyCAP, you can take control of your energy usage, reduce costs, and make data-driven decisions to improve your overall energy profile.
