Time of Use - What is it?
Well it's basically your utility electric rate, which happens to change depending on which hours you use it. (The logic goes, electricity that is being used during "peak" or high demand, should be higher, while "off-peak" low demand electricity, customers should be rewarded with low cost energy.)
But here's the entire post from my friends over at Aurora Solar that goes in quite a bit more detail than I can...
[This article was originally published on the blog.aurorasolar.com/how-time-of-use-rates-work/Aurora Solar blog ." March 21, 2017]
What do the prices of movie tickets to Hollywood’s latest blockbuster and the cost of energy in California have in common? First, in most theaters, you will find that ticket prices change based on the time of day you want to see your show. This is similar to energy rates in California, where the cost of electricity varies based on the time of day it is consumed (an approach known as Time of Use, or TOU, rates). Second, even for a specific time (take a matinee for example), movie tickets often cost less for different types of consumers. Students and seniors, who generally have less income than regular moviegoers, pay less for their tickets than others do. We see a similar phenomenon in California where for a given time period, consumers who use less than a baseline amount of energy, will pay less than those who use more than the baseline amount of energy, even if it is for the exact same time of day. The illustration below shows how California’s Pacific Gas and Electric utility varies the cost of energy based on time of day and cumulative consumption.
For this article, let us focus on the first of these energy rate factors, where the cost of energy varies according to the time of day it is consumed. In subsequent articles, we will at look how rates vary based on level of energy consumption, and eventually look at how utility rate changes will change the returns for solar customers (and how you can optimize your designs to take advantage of it).
Figure 1: E-TOU rates option A during the summertime. Source: www.pge.com.
While California is among the first states to make this type of utility rate structure mandatory for residential customers, it is not alone: in 2015, the Massachusetts Department of Public Utilities adopted default Time of Use rates for residential customers, and the Tennessee Valley Authority (the nation’s largest federally-owned electric utility which serves nine million customers in Tennessee and other southern states) has also proposed transitioning to TOU rates. Time-variable rate programs are already offered on a voluntary basis in nearly every state. Although participation in these opt-in programs has been low to date, as many states consider efforts to modernize the electrical grid and reduce peak energy consumption, TOU rates (and other related time-based rate structures) are expected to become increasingly prevalent.
There are multiple approaches that utilities take when it comes to time-varying energy costs, but Time of Use (TOU) rates, in which customers are charged higher rates for the energy they use during specified peak demand times, are one of the most common. According to Pacific Gas and Electric (PG&E), TOU rates help consumers save money by making the cost of energy low during the time when demand is low. In Figure 1, you can see that the cost of energy is higher between 3pm - 8pm on weekdays than during any other time. During a weekday in summertime, as of March 1st, 2017, rates range from $.317/kWh, to $.393/kWh (for now we are ignoring “baseline” quantities, we will explore that in Part 2 of this series). That is almost a 25% variation between the lowest and highest cost energy! Let us use Aurora to look at a case study where we compare two households to fully capture how this can affect their monthly utility bill.
Household A lives in Bakersfield, CA. We used Aurora’s Consumption Profile to automatically pull up the typical hourly summertime energy consumption for a house in Bakersfield. According to US Climate Data, Bakersfield temperatures range between 64 and 97 degrees in the summertime. Consequently, Aurora by default generated a load profile where air conditioning was a large portion of Household A’s energy consumption (see Figure 2). Unfortunately for this household, about 43% of their summertime energy consumption is going to occur during the time when electricity is most expensive.
Figure 2: Load profile for a house (“Household A”) in Bakersfield, CA generated automatically in Aurora.
Let us now consider Household B, also located in Bakersfield, CA. In this case, instead of using Aurora to automatically generate a typical load profile, we obtained actual measured interval data for a house in Bakersfield from PG&E. We uploaded this into Aurora, which generated the plot below. To make the case more interesting, we assumed that the homeowner has an Electric Vehicle (a Tesla) which they drive about 20 miles per day. This type of homeowner is only spending about 10% of their energy consumption during the peak 3pm - 8pm time zone.
Figure 3: Load profile for a house (“Household B”) in Bakersfield, CA generated in Aurora, based on uploaded energy use data.
If you have been following along, your intuition would suggest that for the same energy consumption, Household A should have a higher electricity bill than Household B, because they are consuming energy during the high-cost period. Before we evaluate the financial implications of Time of Use Rates, let us recap the two households’ information:
Household AHousehold B
LocationBakersfield, CABakersfield, CA
Utility RatePG&E, E-TOU A- Residential TOU Region WPG&E, E-TOU A- Residential TOU Region W
Energy Consumption (July)1,873 kWh1,873 kWh
% of weekday consumption during peak hours (3pm-8pm)43%10%Running Aurora’s utility bill calculator, we find that Household A (high peak consumption) had a bill of $591 for the month of July. We find that Household B (low peak consumption) had a July bill of $561. So despite consuming the exact same amount of electricity, Household A’s bill was about 5.5% higher in July than Household B.
Figure 4: Household A’s July electric bill is $591.
Figure 5: Household B’s July electric bill is $561.
Does this make sense? Mathematically we can get a rough estimate of how much of a difference TOU rates should make in electricity bills with a simple formula:
TOU Bill Difference = (DaysTOU/7) * (ConsumptionpeakA- ConsumptionpeakB) * (URpeak - URoffpeak) / URoffpeak
Equation 1: Rough estimate of the TOU effect on energy bills.
Let us plug some numbers into Equation 1.
Days TOUDays of the week that TOU values apply5*
Consumption_peakAEnergy consumption (kWh) during peak hours for household A43%
Consumption_peakBEnergy consumption (kWh) during peak hours for household B10%
UtilityRate_peakPeak period utility rate **$.393/kWh
UtilityRate_offpeakOff peak period utility rate**$.317/kWh*TOU rates in this region only apply to weekdays
** For simplicity we are assuming that this is for the above baseline energy consumption
TOU Bill Difference = (5/7) * (43%-10%) * (.393- .317) / .317= 5.64%
You can see our quick estimate came pretty close to the actual difference between Household A’s (high peak consumption) and Household B’s (low peak consumption) energy bills. In Part 2 of this series, we will extend this case study to consider how increasing the total amount of energy consumed affects energy bills.
How have TOU rates impacted the finances of your solar installation? Have you used Aurora's modeling software to take TOU rates into account when estimating the value of the energy your design will produce?
Join the conversation on Twitter, LinkedIn and Facebook with the hashtag #TimeofUse and share your insights!