In order to make renewable energy projects successful, there are many factors that utilities need to consider. These include policy drivers, assessing what renewable technologies it will employ, identifying the rates and pricing incentives that could be made available, and how customers can be better engaged. Utilities have created renewable programs with varying degrees of customer participation: some have taken the initiative to provide customers with 100% renewable generated power, others rely exclusively on customers to participate to meet renewable energy goals and the last alternative is a blend of both in which utilities offer customers the option to purchase renewable power matches or install and generate their own renewable power. Overall, the economics of solar and wind technologies are trending in the upward direction—the costs of the technologies are decreasing and the yields are getting higher. Better still, predictive modeling, energy storage and the plethora of research in this area will only make the prospects of integrating renewables more viable.
When considering how to build out a renewable energy portfolio, there are a lot of factors and many points of view to consider. For purposes of this narrative, we will take the point of view of the electric utility itself.
The interest in renewable energy is rapidly increasing with many countries proposing ambitious roadmaps of their power sector renewable integration. So how does an electric utility begin building its renewable roadmap? First, the utility needs to identify what types of renewable technologies are suited for its environment. Using the US, for this example, we of course know that there are some regions that are well suited for hydro-electricity, such as the infamous Hoover Dam area. In drier areas of the Midwest where there are not steady tides or waves that can be used to produce electricity, hydroelectric power is simply not an option. Solar and wind represent a different scenario, whereby all areas have varying degrees of either. The questions for solar and wind energy then become:
How much energy can we generate?
Is it profitable to utilize these technologies?
Is it policy driven?
Let’s start on the concept of how much renewable energy we can generate. Firstly, wind power. Of the approximately 48,800 operating utility-scale wind turbines, majority of them correlate to where the capacity is on the map presented in
In the United States alone, the additions of new wind turbines and infrastructure increased the power capacity for the year 2015 by 41% and powered 88,000 jobs [
fallen drastically, 20% - 40% lower than their highs in 2008. Larger rotors are advancing in technology with increasing capacity and efficiencies. Concurrently, wind energy is selling at lower and lower prices, hitting 2.5 cents per kWh per the report as compared to the national average 11 cents per kWh [
As impressive as the investments in wind energy have been, the global investments in solar have been even greater in recent years (
One of the reasons that solar is gaining so much popularity is due to its versatility. As opposed to wind power, solar can be easily implemented at local business and residential premises. The graphic below shows how along with utility-owned photovoltaics (PV), homes and businesses have a high adoption rate. One of the largest drivers is the continued decrease in costs of solar panels, at about an average of 10% each year since the 1980s [
As presented in
As valuable as solar and wind power may prove to be, they are naturally unreliable― the wind doesn’t always blow, and the sun doesn’t always shine. The energy that can be captured is intermittent. The conundrum, especially in the instance of residential solar
power for example is that when power is being produced (mid) is often opposite of when consumers need it (after work hours in the evening). This defies the premise that electrical supply and demand must be equal at any given moment.
Thus, what is required to make these renewables truly effective is energy storage. Energy storage helps balances the act of supply and demand by storing excess energy and distributing that energy when needed, creating a more flexible and reliable grid system. Deploying energy storage will also reduce and potentially eliminate the need to generate or buy power during high (peak) demand times. Conventional energy storage methods utilized by utilities include pumped hydroelectric (largest storage system operating today in the US), thermal storage, compressed air and hydrogen [
The interest in battery cells for electric utility energy storage purposes can be related to the increased interest and production of electric vehicles. The most prominent example is Tesla who started as an electric car automotive company, now they are also immersing into the energy storage sector with Tesla Powerwall (rechargeable lithium- ion battery product manufactured for home use) [
Predictive analytics are also an important part of the conversation especially with the variable nature of renewable energy such as solar and wind. These are remote monitoring solutions that track the performance of renewable energy productions. Predictive analytics provide a forecast of the amount of energy produced that can be directly supplied to the power grid or stored with energy storage. Predictive analytics software translates data into information which utilities can then possess to make better decisions. With predictive analytics (better yet complemented with energy storage), the utility’s operational efficiency and renewable energy assets life span improves. Various predictive analytics models are developed by various vendors, from the large players of IBM, Accenture to Locus Energy, and Space-Time Insight which is represented in
Overall, the economics of solar and wind technologies are trending in the upward direction―the costs of the technologies are decreasing and the yields are getting higher. Better still, predictive modeling, energy storage and the plethora of research in this area will only make the prospects of integrating renewables more viable.
Renewable mandates are becoming more demanding as well, with more and more countries continuing to adopt renewable energy policies. The Renewable Energy Directive sets rules for the European Union to achieve its 20% renewables target by 2020 (
Many of the US states are looking towards a similar 20% renewable by 2020, and 25% by 2025. California Policies tend to surmount those for the rest of the US. Recently, Governor Brown of California signed a standard into law to mandate 50% renewables by 2030, which is expected to rely heavily on solar [
In order to meet a renewable goal of 20% or more by 2020, utilities and consumers need to be actively engaged. So the question becomes, how do we make it a reality? The utility needs to identify how this affects load curves and revenue generation. Is renewable uptake something a utility wants to do on its own or does it need to encourage customer participation; and if so to what extent? The utility also needs to determine if they will accept consumers putting power back onto the grid, and if so how much will they pay for it? Is it something they can pay at a retail or wholesale price? If the utility is seeking to increase its renewable portfolio for economic or policy reasons, are there opportunities to provide rebates?
Let’s begin with a case study of a utility that has made the business decision to take control of the renewable conversation. In 2014, Georgetown, TX finalized a 150-mega- watts solar power agreement and a 144 megawatt wind power agreement that “will make the City of Georgetown one of the largest municipally-owned utilities in the US to supply its customers with 100 percent solar and wind energy [
What all of this means is that all customers throughout the utility’s territory will be getting clean power―no residential or commercial solar or wind generation required. What’s more is the utility rates for customers are expected to stay low; residential customers currently paying $20/month customer charge plus $0.0939/kWh. Georgetown utility is continuing to receive customer requests regarding rooftop solar. The decision on whether or not the utility will recognize residential or commercial wind or solar after they’ve achieved a 100% renewable status in 2017 is yet to be determined. Largely, customer education is expected to be a major factor in navigating through the customer owned renewable conversation.
Majority of utilities are not in a position to take renewables completely in house as Georgetown has. Another model is to offer customers the choice of generating their own renewable power or giving them the option of purchasing renewable power from their utility company. Pacific Gas & Electric (PG & E) for example, offers a “solar choice” for its customers in which they can opt to have 50% or 100% of their monthly power matched with solar power provided by the utility. Instead of purchasing and install rooftop solar, customers can pay a premium for the service through their utility provider. PG & E offers a rate calculator to assist customers in understanding the costs. For example,
Like PG & E, SMUD offer its customers both the option to self-install or participate in a community solar program. SMUD’s SolarShares program is setup so that customers pay a flat monthly fee to subscribe. On the SMUD website, they describe the structure further as such: the fee is based on your historical energy use and the share size you
select. You will then receive energy credits to your bill for the amount of solar power your SolarShare generates. Both the flat monthly fee and the energy credits from the solar power will be combined on your SMUD bill [
Now, let’s take a look at various examples of how the customer-owned renewable programs are managed. In January 2016, the California Public Utilities Commission (CPUC) voted to enact a policy that would ensure net-metered customers earn retail-rate payments for their surplus solar energy. The decision also comes with requirement for solar customers to move to time of use (TOU) rates “that charge different prices during different times of the day, to better match real-time costs of generating and transmitting energy across the grid at large [
Unlike California, many Texas utilities have not adopted net-metering policies for their end-users, nor are they required to do so. However, there are some utilities such as Texas Gas Service who offers solar water heating rebates. Other Texas utilities including Oncor, Austin Energy, CPS Energy, El Paso, AEP TCC and AEP TNC have solar incentive options, but vary from one to the other [
New Jersey is working aggressively to increase solar across the state as part of its Renewable Energy Incentive Program (REIP) targeting a 30% renewable target by 2020. New Jersey is the fastest growing market for solar in the US and “one of the largest in terms of installations and installed capacity, second only to California. Much of this success is due to New Jersey’s Solar Financing Model, which relies on high renewable energy standards and the use of Solar Renewable Energy Credits (SRECs) [
The utility energy transformation is here, and renewables are undoubtedly a major component. In order to make these projects successful, there are many factors that utilities need to consider. These include policy drivers, assessing what renewable technologies it will employ, understanding how these will be integrated into the grid, identifying the rates and pricing incentives that could be made available, and how customers can be better engaged. With all factors considered, the utility will be equipped to build out a thoughtful renewable roadmap.
Griffin, N. and Si- laban, A.G. (2016) Powering Renewable Pro- grams: The Utility Perspective. Open Journal of Energy Efficiency, 5, 148-159. http://dx.doi.org/10.4236/ojee.2016.54013