9/26/2016 U.S. Energy Storage Market to Grow 8x by 2020: What If It Had Its Own Special Tax Credit?Read Now Source: GreenTech Media Can the energy storage industry withstand the scrutiny of having their own ITC? It cannot be understated how transformative an energy storage ITC would be for the industry. At IronOak Energy, we have written previously on the impact of such an ITC, and even presented a positive take on its potential rollout. Here, I want to pose the question of whether the industry is really ready for such a game-changing policy. The graph above shows projections for the growth of energy storage development under the current policy regime. Not too shabby. But is the energy storage industry prepared to put that delicious tax equity to good use on stand-alone energy storage projects (in practice, solar + storage applications currently qualify for the solar ITC)? Of course, the answer is always: it depends. Depends on what? Some would argue that the critical issue holding back a tidal wave of energy storage projects is the technology. One could easily view the vast array of energy storage technologies vying for prominence with some trepidation. Some are commercially viable, while many are not. It takes some brainpower to suss out the contenders from the pretenders. Even the smarties at MIT have a tough time doing it. Do we want the government to incentivize the deployment of technologies that may not be ready to contend for the main stage? Conversely, is that precisely the role we want the government to take? The double-edged sword of government subsidy This is a classic double-edged sword phenomenon. On one edge, there are green grassy fields of opportunity in rolling out new storage technologies in commercial applications. Accelerating storage deployment will drive down costs and help evolve viable business models. Beautiful. Lurking on that other edge is the distinct possibility that many storage technologies in earlier stages of development will simply fail. And failure is bad press, even if it is the Darwinian process of technological progress. It puts the government in the untenable position of having subsidized a “reckless” experiment with taxpayer dollars. “Picking winners and losers” they will say, even though an ITC is designed to avoid precisely this potential conflict. And, let’s just say that there is a history of nasty repercussions for such interference with the so-called free market for energy (ahem - myth). Solyndra - need I say more. Some will say that Solyndra was blown out of proportion (it was) AND it was 5 years ago (a lifetime ago in the clean energy industry). To top it off, Solyndra was backed with loan guarantees, not really what the ITC is about. Details, details... But now, the vengeful energy gods have gifted us SunEdison. It was an altogether explicable collapse, but one that, nonetheless, provides ammunition against government support for the clean energy industry. Who knows what would have happened with the extension of the solar ITC if SunEdison has filed for bankruptcy in 2015 rather than 2016. So, be careful for when you wish upon your industry the scrutiny of being a target of government support. Technological risk is a red herring -- it is really all about how to finance storage Sure, risk exists with many energy storage technologies. Even the most established battery technologies lack the operational history to assuage the concerns of investors looking at decadal time horizons. If you are absolutely intolerant of risk, go invest in government treasuries (just kidding - terrible idea). Just running down the ladder to the cheapest storage technology fails to capture the complexity of the underlying value proposition. Cost is king, but there are many other factors competing for a role on the king’s court. Energy storage technologies cannot be reduced to a simple efficiency or production metric, as with solar or wind (even that is an oversimplification, but at least a reasonable one). There are more than a dozen potential services that could be generated by a given storage technology, many of which have few established market mechanisms to generate reliable revenue. So, here’s the central takeaway. The biggest challenge in the energy storage market is not how to choose the right technology. It is how to design the right market structures to support financial innovation. Making energy storage bankable is close to being a precondition for the successful utilization of an ITC. Recall that the success of the solar PPA model hinged on stable, contracted cash flows. Making solar bankable unlocked a vast market potential that we are still in the early stages of witnessing. There is no equivalent financial structure with energy storage, yet there remains a distinct need to create consistently financeable project cash flows. But wait, SolarCity and Tesla (perhaps soon to be joined in holy matrimony) pioneered a solar + storage PPA earlier this year. The energy storage industry needs a financial product the equivalent of a PPA, and perhaps we are not too far off. Thus far, it has taken a savvy, not mention risk tolerant, investor to back energy storage projects. There is only so much runway with this sort of approach. Easing the path for new investment in storage will hinge on making this inherently complex technology and market application simpler. There are already frontrunning markets generating experiences that will guide future market design and development - thanks, California. In tandem with this type of market development, energy storage needs a greater degree of standardization of financial strategies and structures to help make projects pencil. And not just for the smartest guys in the room, but for a broad swath of interested investors. The question remains as to whether an energy storage ITC will aid or inhibit such progress. Related Reading:
Related data points:
Amid the buzz of Solar Power International 2016 last week, there was a persistent cry of the financing gap in C&I solar. Yes, big money is flooding in searching for good projects to finance. The low-hanging fruit has always been utility-scale solar. Scale, credit-rated offtaker, stable cash flows - check. But margins are being squeezed as the race to bottom out PPA prices builds momentum. Enter C&I solar - a tantalizing large potential market of smaller-scale projects, trending towards 3rd party ownership (translation = welcome investors!), with low hanging fruit ripe for the picking. Commercial and industrial offtakers seem more willing than ever to sign up for solar, and at PPA rates often substantially higher than what can be gotten from our utility friends. But, is C&I solar the greenfield opportunity that many hope it to be? (Source: GreenTech Media) C&I solar is not blessed with the same attributes as a utility-scale project - smaller scale, offakers with no credit ratings, and, most importantly, extreme heterogeneity. Diversity is every infrastructure financier’s nightmare, as it stymies standardization, which is the key ingredient to scaling investment from more risk-averse, low cost of capital investors. And the C&I solar market has bedeviled many attempts to solve the standardization challenge. By way of example, I am going to pick on beEdison and their flagship risk analytics product, truSolar. TruSolar, a project cofounded by Distributed Sun, Dupont, RMI, and Underwriters Laboratories, was an attempt to create a uniform method for assessing project risk in C&I solar. The truSolar Risk Screen Criteria and Methodology (RSCM) identified over 800 unique risk elements and thousands of scoring dependencies. Impressive? Or overkill? Hard to say. On top of this great risk analytics tool, they created a marketplace platform, used a ton of project data to train their risk algorithms, created nifty flow charts like the one below, and hoped that buyers and sellers would seek holy matrimony at their table. By all accounts, truSolar is the real deal, and who doesn’t like marketplaces, but are buyers and sellers coming? They built it, so did they come? beEdison claims to have 200 members and 1,000+ projects totally over 4 GW and $10B of dealflow. But, I have to admit - I am skeptical. Around 2 GW of solar was developed in Q2 2016, and less than 20% of that was in C&I market (SEIA). So, it appears as though the 4 GW number is just maybe a bit of an overstatement. (Source: beEdison)
To be sure, I am fan of beEdison’s approach. It is ambitious, and it solves a real challenge in the solar C&I market using - everyone’s favorite buzzword - BIG DATA! So, why is it not sweeping through the marketplace with wild abandon? Perhaps, they made the risk analytics process too opaque and complex. Perhaps, sellers do not trust the idea of using a platform to meet sellers, or vice versa. Or, perhaps the real issue is that solar C&I projects are not penciling like investors would hope. The real challenge in the solar C&I market is not just standardization and credit analysis. It is that these projects do not turn out to be nearly as rich as investors had hoped. It is a classic case of failing to achieve economies of scale. Development and construction cost efficiencies in the utility solar market allow projects to pencil even with really low PPA rates. It is really difficult to translate those cost efficiencies into the C&I solar market due to the aforementioned issue of extreme heterogeneity. Said another way, solar C&I projects just cost more. And only in niche markets can those high project costs be supported by the prevailing PPA rates that a C&I customer will accept. Many geographies are blessed with low retail electricity rates, especially for large electricity users. These offtakers are not likely to accept a PPA which locks them into a higher electricity cost today, even if the long-term impact will likely be in their favor. When high development and construction costs run up against this ceiling of acceptable PPA rates, you start to see margins squeezed. But the difference is that these margins are on small projects with funky risk profiles. So for the time being, solar C&I remains a “diamond in the rough” market. Investors are seeking the gems out there, while many (I mean, many) projects out there just fail to meet their hurdle rates, risky or not. But be on the watch - there are many other companies exploring ways to serve this sector efficiently, and at scale. The real gamechanger may not be nifty platforms, but rather the tried and true method of securitization. Solar securitizations are happening, pioneered by SolarCity and SunRun, but can the question remains as to whether they can open the floodgates of institutional capital given the fragmented and idiosyncratic nature of solar C&I projects. Nobody likes paying more than they should. And my dad is a CPA, so this is definitely true for me, too. But this barrier is not unique to renewable electricity. The same expectation is true for most non-luxury goods and services. Yet I still hear the objections everywhere -- from sophisticated investors to family friends -- that solar and wind are too expensive. Is that still true? Yes, but increasingly no. OK, to be clear, most of the data says no, but as you know, perception is reality. This lingering misperception is also being observed by other energy leaders, including the Director of Sustainability and Cleantech at Schneider Electric in recent a Greentech Media article about Scheider’s New Energy Opportunities (NEO) Network. Consider the graph below from Clean Edge, which is based on data from the US Lawrence Berkeley National Laboratory. The levelized costs for solar electricity (LCOE) has fallen from 22.5 c/kwh to less than 5 c/kwh. That’s a roughly 78% drop in price over the last 10 years. But unless an investor or corporate executive has regularly re-evaluated the business case for alternative energy, they might have missed these market changes. It’s important to note that this refers to utility-scale solar, not rooftop solar. The latter has a higher LCOE (c/kwh), but it also competes with higher retail electricity rates. Additionally, Deutsche Bank estimates that unsubsidized rooftop solar is 30% cheaper than retail power prices in many countries. See their map below showing countries with substantial areas of grid parity. Finally, here’s another data-driven perspective from investment advisory firm, Lazard. The resolution is not great, so let me help you out. Here are some of the lowest LCOE values from highest to lowest:
Here’s a link to the full Lazard report, version 9.0.
If you like data and charts, you’re going to really enjoy this. Grab a big coffee and settle in for some quant goodness. And next time someone says that solar is too expensive, you can admit they are partially right. But then give them a little dose of 2016 data. Does every solar project have to be big? Many solar investors’ intuition rests easy when they see the graph below. It fits into the elegant framework of “economies of scale.” The bigger the project, the lower unit cost of installation. The smaller the project, more cost-inefficient. Going big is part and parcel with cost efficiency, or so the saying goes. (Source: Lawrence Berkeley National Laboratory) But be careful, this is precisely the rationale used to advocate that utility-scale solar is the only form of solar in which we, as a society, should be investing. Heck, Warren Buffett believes so, and that guy never makes a bad bet (at least publicly). Why produce electricity from projects that can be built at $4/MW on top of a house, when you can generate those same electrons from a larger project that can be built for half the cost? It is a compelling argument, I must admit. But it suffers from the same “big infrastructure” fallacy that is currently hamstringing our legacy centralized energy system. Build BIG projects for cheap on a per MW basis. Big is cheap and efficient. But, as any good economist knows, external costs can cause headaches (and asthma, skin cancer… you get my drift). Utility-scale projects have gotten a free ride See, BIG projects are cheap, in part, because they burden society with costs not borne by the projects themselves. What costs you might say -- only the never-ending litany of transmission and distribution expenditures. Billions of dollars of deferred T&D expenditures hang like a dark cloud over electric sector. And who is paying for those? Not the project owner, that is for sure. Yes, there are interconnection costs, but let’s be real, they hardly cover it. That is not to say that there is not, in fact, a significant need for big projects. But only to a certain extent. Why only build projects that necessitate that we continue to invest so heavily and T&D infrastructure? Small can be beautiful (and efficient), too. Yes, we should invest in more high voltage DC transmission. But, why not minimize the need for such costly investments by building smaller C&I and residential projects? They may be more costly on paper, but at the scale of the whole grid, they may actually be introduce some much needed cost-cutting. Thus, it is the prospect of avoided T&D costs that gives any credence to the claim that smaller-scale projects can be both both prudent and cost-efficient. Avoided costs is a common concept in utility-scale generation, but, for some reason, this logic is not applied to smaller-scale projects. It is not because they don’t make sense, it is because utilities are uncomfortable with power producers that they do not control. Investors start to take notice of smaller-scale solar Now, from the perspective of an investor looking to be a long-term project owner, things get interesting. The graph below show the slow march down the path of PPA price decline. (Source: Lawrence Berkeley National Laboratory)
On the one hand, great - solar power is getting cheaper, and fast! On the other, there is a palpable sense that there is large-scale suppression of investors returns taking place. Fair enough. Once a market matures, actual or perceived technological risk reduces, and returns should decrease. But that does not stop investors from feeling the squeeze. And that squeeze is happening particularly in the utility-scale market. In part because utilities have a lot of negotiating power in many markets, PPA prices are plummeting, some creeping below the $0.04/kWh threshold. There is still value to be had, but the pressure to find good deals has encouraged (ahem… forced) investors to look back into the C&I market for the returns they seek. This is great from the standpoint of increasing access to capital for a market segment which historically has been more difficult to finance. Less standardized and smaller projects, diverse off-takers, many without credit ratings, and less financially robust developers have all hampered the expansion of C&I solar. But, now the suppression of utility-scale solar returns has led investors to start poking around the sleeping giant of C&I solar. Many C&I off-takers have the ability and willingness to pay much higher PPA rates than utilities. Translation = sweet returns. And, there are a LOT of them. If you are lucky enough to find them in places like Nevada where many large-scale C&I customers have been summarily pissed off by the antagonistic treatment by the utilities commission, then you could make some big waves. And, as C&I developers have become more sophisticated, projects are trending towards more consistency, bankability, and less risk. So, keep a lookout as the C&I solar market starts to find that sweet spot in the classic risk vs. return story. Small can be beautiful in the solar market. You’ve seen many headlines touting “record new solar panel efficiency.” We get excited seeing those, too. But they don’t matter. Alright, that was shock value. Let me explain. First, take a gander at the mind-numbing chart from the US National Renewable Energy Lab (NREL) below. This is one of my favorite figures in the whole world. Now, please memorize it -- there will be a quiz later. (Or so I tell my corporate and military executive students. They laugh at my false threats.) What does this figure say to you? Three potential takeaways: 1. There are way more types of solar panels than you thought, right? 2. Solar panel efficiencies have improved considerably between 1975 and 2015. Duh. 3. The guys doing the stuff in red font should get new jobs given their low efficiency. (Not really. Those are super cheap organic polymer-based solar cells. Their future will come one day.) OK. Now forget that graph. Look at these two more important charts from Bloomberg. Do you see any relationship between these the red and blue lines? (I hope you do.) Cost falls. Solar installations go up. And now for the next chart. Yes, you are reading that right. A 99% drop in solar panel prices since 1976.
I know, I know. I hear the devil’s advocate: But doesn’t greater volume of solar installations drive down costs? Yep, but the opposite is more true. Cost drives volume. China got in the manufacturing game just as the recession of 2008 hit and EU solar demand fell off. Solar panel prices fell faster and haven’t really stopped, resulting in an 80% drop prices in the last 8 years. For more data and graphs about solar's falling costs and coming world domination (insert dramatic music), see energy rockstar Joe Romm's piece "You’ll Never Believe How Cheap New Solar Power Is." In case you fear that my ponytail is getting in the way of my PhD and love of private equity (insert humor), and that I'm being too kind to solar, consider this projection from Bloomberg: By 2040, global investment in solar will total $3.4 trillion, while fossil fuels and new nuclear will only receive $2.1 trillion and $1.1 trillion, respectively. One word: Yikes. So what? The next time you hear a sales pitch about panel efficiency, praise them for their ingenuity. They are real wizards. But just keep asking: What is the resulting $/kwh and Internal Rate of Return of the solar project? Efficiency is the finger point at the moon. Please go after the moon. (Source: RMI Electric Vehicles as Distributed Energy Resources)
Where are you, rational car buyers? The myth of the rational economic man lurks around the issue of electric vehicles (EVs). See, rationality is something to which many learned folks aspire, but it turns out to be a mirage. Yes, we stumble towards it in a thirsty stupor, dreaming of drinking up its cool, clean sensibility. But, we never get there. It always remains a misty illusion just out of reach. The rationality dilemma with EVs is pretty simple. Let’s make it clear -- EV purchasers are no more rational than EV skeptics. EV purchasers will look at the graph above, and say -- ha! -- I am saving money on a per mile basis compared to all of your fools with internal combustion engine (ICE) cars. They are not wrong, but neither are they entirely right. EV skeptics will look at the graph above and say -- ha! -- you are being duped into assuming this is an apples-to-apples comparison. Again, they are right, but that is not the whole picture, either. Why you are going to lose the “EVs are cheaper over the long haul” debateIt boils down to this. Yes, electricity is a great source of energy, and it is cheaper on a per mile basis than gasoline (even the highly subsidized gasoline that we enjoy, and abuse, in the US). But electricity is electrons, difficult to contain, eager to be used immediately. Gas is a portable, energy dense liquid fuel that affords the owner of this magical worker unsurpassed flexibility in how and when to use it. Ironically, in certain places electricity and gas are made of the same stuff -- oil. I am looking at you, Curacao and Gibraltar, where 100% of electricity is generated from oil! So the real calculation about EVs is more complex because the services that you gain from gas and electricity are not interchangeable. What value do you place on your American right to cruise the highways to your heart’s delight? If the answer is high, then the comparatively lower cost of an EV-mile is meaningless. Your peace of mind in hitting the road without a worry in the world as to how your next mile will be fueled is, in economic terms, infinite. It trumps all other concerns. The term of art for this is “range anxiety.” What value do you place on cheap, clean transportation within a relatively small driving radius? If the answer is high, then the EV vs. ICE cost comparison is how your explain to your beloved significant other why you just purchased a car that cannot comfortably drive the family to visit your in-laws. Oh, and by the way, the sticker price was a little steeper than that conventional car you had agreed to purchase. But really, the EV question is even more complicated than that And that is just the tip of the iceberg. There are many other factors -- your comfort with rapidly improving battery technology, your assumption that EV charger networks will continue to expand, your belief that manufacturers will not bail on EVs in the future, etc. -- that ultimately weigh heavily on any rational calculation justifying or dismissing the idea of purchasing an EV. Dilemmas breed a “let’s wait and see” attitude, how boring Which brings me to the last point. I grant you permission to purchase (or lease) an EV (or PHEV if just want to dip your toes). Don’t feel like you have to explain yourself to your neighbors (though this tactic will not work with your significant other). After all, why did they buy that Honda Odyssey? Was it on a purely rational, benefit-cost maximizing basis? No, they wanted something comfortable and reliable for the family, period. They just wanted it, just like you just want an EV. And let’s be real, you want it because it is cool, wave-of-the-future technology. Because it allows you to avoid ever patronizing another neerdowell, franchised Exxonmobil (or BP, or Shell, or fill-in-the-blank) gas station. Or maybe you just like getting all the best EV charger parking spots. It doesn’t matter - embrace the irrationality. Be an early(ish) adopter. Get onboard, because EVs are where we are headed, like it or not. Queue EV hockey stick graph. (Source: GreenTech Media)
Co-ops and munis finally get a spot at the clean energy table In the energy industry, utilities have long run the show. The transition to clean energy is undercutting utilities’ historical dominance of how electricity generation, transmission, and distribution occurs. Distribution cooperatives and small municipal utilities have long ridden on the shoulders of these giants, working through contracts that typically stipulate that they must purchase nearly all of their electricity from generation and transmission (G&T) providers. In most contracts, a whopping 5% has been the limit placed on their self-generation, rendering these smaller players [almost] powerless in determining their own energy future. There is some poetic justice in having the small folks granted a spot at the distributed clean energy table. As electric cooperatives and municipal utilities were severely handicapped in their ability to procure their own electricity, they have only dabbled in contracts with independent power producers (IPPs) and other clean energy generators. This came to a head with probably the most unsuspecting sounding cooperative you could think of, the Delta-Montrose Electric Authority (DMEA). As a member-owned, rural electric cooperative based out of southwest Colorado, it is not hard to imagine that the time would come when they would want to be afforded the right to procure their electricity from whoever they please. In an act of magnanimity that perhaps surprised many, the Federal Energy Regulatory Commission (FERC) ruled in favor of DMEA in their case against Tri-State, another cooperative that provides generation and transmission services to 44 distribution co-ops across five states. In short, the ruling lifted the limit on DMEA’s ability to procure electricity from renewable qualified facilities (QFs). The loophole, of sorts, lies in the fact that the Public Utility Regulatory Policies Act of 1978 mandates that utilities must purchase electricity from QF projects. The de facto interpretation of PURPA, for oh the last 38 years, has been that larger-scale utilities and G&T providers would be sole purchaser of electricity from QF projects. DMEA, in a moment of true inspiration, said “to hell with that,” and managed to supersede their contract with Tri-State by asserting that they are themselves a utility, and should be afforded the same rights. This move did not ingratiate DMEA to Tri-State, to say the least, and Tri-State attempted to impose an exit fee on DMEA, which FERC summarily rejected. Message received. Renewables on the grid will no longer be a unilateral decision. Co-ops & Community Solar = Match Made in Heaven It is not hyperbole to claim that this is a game-changer for the nation’s 905 electric co-ops and 835 municipal utilities who woke up following this FERC ruling to a new world of opportunity. How fitting. Co-ops and munis were probably on the leading edge of support for renewables, and now they have license to act on their values, rather than be subjected to energy procurement decisions out of their influence. And that is a very good thing. In fact, it is 987 TWh/yr of a good thing, which if you do the math, implies that the potential market for co-op/muni renewables approaches 400 GW. Many co-ops and other smaller utilities are structured in ways that are much more conducive to serving the public good. Often they are publicly or member-owned, or at the very least not publicly traded, which makes them more intimately connected to their customers and ratepayers than the larger utilities and G&T providers that dominate much of the electric power procurement space. Moreover, they are more likely the engage in novel project types like community solar. There is some cosmic symmetry in enabling co-ops/munis to sponsor community solar projects. It makes so much sense. It seems ludicrous that this was ever challenging to execute at a meaningful scale for many co-ops. According to RMI, the market for community-scale solar projects ranging between 500 kW and 5 MW of capacity each could exceed 10 GW by 2020. Wake-up Call for the Generation and Transmission Providers An ancillary benefit of this new arrangement is that community solar projects may now be easily integrated into the local distribution system, therein avoiding many costly infrastructure upgrades. Translation: electric distribution co-ops/munis may be able to purchase power directly from QF projects at a lower cost than what they are currently charged by their G&T providers. Memo to G&T providers. This also means that they will be reducing their reliance on your services and undercutting your revenues, unless you can evolve together into helping to co-create a clean energy future. Now, there are limits to be sure. Electric distribution co-ops/munis have only been afforded the right to negotiate PPAs (and not just based on avoided costs, as in the past) with QF projects in their territory. Not a bad deal, but it does not make them an autonomous entity. Co-ops/munis still have to balance their energy supply, which can only be done through grid management in the transmission and generation system. So, there may be some building tension in the marriage between electric distribution co-ops and their larger G&T brethren. No one wants to see the G&T providers go extinct. In fact, they are still a critical species in the electric grid ecosystem. But, the challenge will be in better collaborating and coordinating with their member co-op/muni friends. This is not a reach. And there is no better time than now. Look for inspiration? Well, look no further than RMI’s Shine Initiative, an innovative program aimed at helping accelerate solar procurement in the community-scale market. Fragmented Commercial and Industrial Marketplace The recent barrage of articles detailing the bankruptcy of a renewable energy giant (SunEdison) and the pending sale of Elon Musk’s third favorite company (SolarCity) has been nothing short of suffocating. IronOak Insights contributed our own sobering account to the stockpile of SolarCity acquisition articles last week as we didn’t want our readers to think that we were living under a rock. But outside of those two headline grabbing companies lies a diverse ecosystem of large scale developers working to expand the commercial and industrial solar landscape. Per the graphs below, while only 42% of the U.S. residential solar market in 2015 was serviced by regional installers, 70% of the C&I solar market in 2015 was serviced by companies whose names were not SolarCity, SunEdison, Sunpower, or Borrego Solar. Let’s dive into some of the activity within the fragmented C&I solar marketplace. Leading Residential Solar Installers in the U.S. in 2015 (market share by MW installed) (Source: Statista) Leading Non-Residential Solar Installers in the U.S. in 2015 (market share by MW installed) California’s Cash Crop
As the perpetual leader in the U.S. solar race, California dominates every other state with its relentless pipeline of large-scale solar PV projects. The state’s consistent appeal exists because above-average electricity rates are coupled with some of the best insolation in country, along with a small state program called the California Solar Initiative. In addition to solar electricity generation, all of that sunshine has long supported California’s agriculture industry, and now California-based solar developers, like CalCom Solar, are targeting Ag companies as perfect companions for mid-scale PV facilities. CalCom recently completed a 2.2 MW solar farm for a fruits and vegetable grower, and the single-axis tracker installation now stands as the largest customer-owned, net metered system in Monterey County. CalCom is one of many developers across the country that are leveraging USDA REAP (Rural Energy for America Program) grants along with the federal ITC to provide attractive PPA rates for applicable off-takers. PFMG Solar (Partners For Many Generations), a top 15 U.S. solar developer, also takes a targeted approach in California by focusing on mid-scale solar solutions for suitable school districts. PFMG recently completed a 1.5 MW installation for a California school district and they’re a likely candidate to pick up some of SunEdison’s solar assets related to education centric off-takers. Full Steam Ahead in Colorado and North Carolina Just this week, Xcel Energy received the Colorado Utility Commission’s approval to move forward with the utility’s plan to develop 29.5 MW of PV from community solar projects. This is welcomed news for Denver-based community solar developer SunShare who commissioned a1.5 MW community solar garden in Arvada, CO on June 21st. SunShare joins Community Energy and Clean Energy Collective as the three juggernauts supercharging the community solar space in Colorado. Community Energy made headlines recently when they offloaded six North Carolina-based projects to Duke Energy with a total capacity of 30 MW. North Carolina’s solar market has remained strong despite the repeal of the state’s lucrative 35% solar tax credit. San Francisco-based Ecoplexus also recently completed six projects in NC, totaling 54 MW and requiring $79M in total investment. Ecoplexus has 36 MW under construction and claims more than 1 GW in their development pipeline that spans across 12 US states and dispersed international development. The West Texas Solar Patch Have you ever imagined an oil field man camp with LED lighting, tankless hot water heaters, and bike racks? Me neither, but maybe that concept becomes a selling point for solar field workers relocating to West Texas for the impending solar boom. ERCOT, the grid operator that services 90% of the Texas electric grid, is anticipating more than 560 MW of PV to be installed in Texas during 2016. That’s more than double the 212 MW installed during the previous year. Texas already ranks 9th in the U.S. in terms of installed solar capacity, and many analysts are expecting that ranking to climb up in the coming years. Texas, specifically West Texas, has some of the highest insolation in the U.S., large tracts of suitable land, low regulatory costs, and above average electricity rates. Although solar produced electricity will only account for 3% of the state’s generation capacity in 2017, ERCOT is projecting solar to supply more than 17% of the state’s electricity by 2030. While a large percentage of the anticipated development will come from utility-scale developers including First Solar and Recurrent Energy, regional developers will still have the opportunity to fill a void in the marketplace. I recently spoke with a developer that was already complaining of long interconnection study delays, so make sure to get your paperwork started sooner rather than later. Solar securitization has been a popular theme at IronOak Energy, and for good reason. Access to gobs of low cost capital is every solar developer’s dream, along with, of course, limitless net metering (but what about Value of Solar?), a permanent ITC (debatable), and friendly utilities (now you know I am reaching - just kidding...kind of). As opposed to the other items on the solar developer wishlist, solar securitization is actually happening in real time. Pioneering companies like SolarCity and SunRun are paving the way with new securities offerings as we speak. The market is not huge, but has crested the $300M mark in 2015. This past January, SolarCity completed its first securitization of distributed solar loans, and achieved the industry’s first investment credit rating. Others will undoubtedly follow, if the way is clear. Back in June of 2015, we wrote about the idea of solar securitization finding more traction in the market. But, be careful what you wish for. While securitization may be the shiny new-ish finance toy for the solar industry, it is not a one-size-fits-all solution to finance (or refinance) projects. But be wary of the double-edged sword of solar securitization The solar industry rides on the shoulders of tax equity investors, at least until the ITC is phased out. As such, one must consider — how would securitization change the project finance equation? For one, securitization would expose tax equity investors to potential recapture of any unvested credits. Translation - backing a security with projects that do not utilize any tax equity will make the deal much simpler and more palatable. But who wants to leave money on the table? Luckily, the inverted lease was designed to tackle sticky tax equity issues like this and can be used to mitigate this recapture risk. As of 2014, SolarCity and SunRun started to create solar securities primarily of inverted lease arrangements. Problem solved. But that is not really the only issue that should concern project developers. The dark cloud hanging over solar securitization is that developers or third-party asset owners would have some of their upside undercut due to the fact that their equity in the underlying assets relies on retained value. Equity holders are always at the end of the cashflow line, but adding security holders to the mix places yet another claim on the project cashflows before equity holders get a piece of the pie. And that pie needs to be comprised of sweet, high-grade offtakers. As we all witnessed in the mortgage-backed security debacle, bundling lots of disparate (even toxic!) assets into a nicely packaged security may doop the market for a while, but it will come back to bite you. The same holds for solar-backed securities. Which means that not every residential or C+I solar project is going to pass muster as a security-grade product. This is one of the reasons that the initial transaction costs for creating a security are substantially higher than essentially any other project finance mechanism. High transaction costs along with the additional cost burden of compliance reporting can start to eat into that delectable low cost of capital, unless you have your ducks in the row. Some seriously good reasons to dip your toes into the securitization pool The first thing that you probably said when trying to sound smart about investing was “diversification.” I’ll wager the second thing you said (and you really had no idea what this meant) was “liquidity.” Diversification and liquidity are two of the primary ingredients in the low cost of capital cake mix. Diversification because high concentrations in terms of geography, offtakers, operations, and policy attract those pesky risk premiums that increase the cost of capital. Liquidity because it is the lubricant that allows markets to function and buyers and sellers to repeatedly engage in transactions. Add in a little sponsor bankruptcy risk mitigation and some public credit ratings to the mix and you have the makings of a very enticing offering to gargantuan fixed income institutional investor class. And what do institutional investors like more than anything? You guessed, boring standardization. All those legal and accounting fees that allow you to create boring, standardized securities also unlocks a velocity and scale of financing that could leave traditional project financing in the dust. Institutional investors have been invited to table, but will they dine? As we know, institutional investors have a big appetite, which, in the case of solar, has meant that they can only find the requisite scale in bigger utility-scale deals. Securitization could hold the key to allowing smaller residential and C+I projects to access lower cost capital from institutional investors. This issue of scale is a big one though. Securities of the size that would attract institutional investors have been few and far between. The question of the day is who can follow SolarCity and SunRun’s lead to bring the solar securitization market out of the hundreds of millions and into the billions. Related data points:
Further reading:
(Source: IEA) The International Energy Agency must love the Stanley Cup Playoffs because their recently published Global EV Outlook was full of hockey sticks! The hockey stick graph, you may recall, was popularized as a key piece of evidence supporting the existence of climate change. Rest assured, there will be no debate of climate change here. I am a deep believer in the appropriate use of sports metaphors to describe complex phenomena. The greenhouse gas emissions hockey stick graph tells about as simple a story as can be told about climate change. The hockey stick is a pithy way of showing how a creeping linear trend jumps into an exponential growth (or decay) phase. Our minds are wary of things that change exponentially. They are just not normal. That is because from one time period to the next, your worldview, let’s call it your umwelt, is dramatically different. Yet, as history shows, this Law of Accelerating Returns holds to key to understanding technological progress over the course of history. We see hockey sticks everywhere now. Some, we should get excited about like renewable energy deployment. Others, we might be wary of like the growth of the economy. Some indicate a phase shift, as in the case of the transition to renewable energy. Others might indicate a boom-and-bust cycle, with exponential growth followed by precipitous declines. The trick is understanding the underlying drivers of change. So, about EVs. Not long ago, EVs were very rare, too expensive, and only the most ostentatious environmentalist among your friends was even considering buying one. Skip ahead five years, and all of sudden, your umwelt has changed. The Law of Accelerating Returns has been hard at work. Now, you are starting to see EVs everywhere you look, EV charging stations are taking up the best parking spots, and your neighbor down the street likes to park their EV in the driveway to show it off while it charges. And this is just the beginning. (Source: IEA)
What changed? Well, largely it was a story of rapid technological innovation leading to dramatic cost reductions. The most important of these is with the battery, of course. As batteries make up around ⅓ of the cost of an EV, the increases in energy density coupled with the reduction in battery cost have started to bring EV costs down from the stratosphere. And not to dismiss, also helped alleviate the all-important “range anxiety.” We Americans do have a pastime of hitting the open (or congested) road without a worry until the next gas station. If battery technology continues its march of progress, look out for the Law of Accelerating Returns to come into full force in the EV sector. Feed In Tariff (FIT) programs have been the lynchpin of solar growth, but is it time to move on? Source: Earth Policy Institute/Bloomberg Feed-in tariff (FIT) programs were designed to entice new entrants into the solar market during a time of learning and experimentation. Initially, they were designed as value-based instruments in which compensation was tied to various external benefits, such as avoided externalities (fancy term for coal plant pollution). But this model was a bit pie-in-the-sky, and left a lot of uncertainty and unpredictability on the table for investors and developers to navigate. The resulting high project financing costs ended up being a major deterrent to the type of catalytic growth that was hoped for. The real magic of the feed-in-tariff was unlocked when there was a shift to cost-based instruments, wherein a solar developer would get compensated for the costs of development plus some reasonable rate of return. The fixed-rate, long-term guarantee of cash flows was music to investors’ ears, and the solar market was off to the races all across the EU, China, India, and South Africa. Interestingly, no North American country has instituted a FIT program to date, and rather have opted for more circuitous policies such as Renewable Portfolio Standards. We now have a solid track record by which to evaluate the successes (and failures) of FIT programs around the world. On the surface, much of the success of solar markets worldwide is attributed to FIT programs. But there is a creeping concern that this success will not last much longer. FIT programs solved one problem by creating stable, long-term cash flows for solar projects, which could be underwritten and financed by savvy investors. This accelerated adoption and experimentation with different technologies and business models, but more importantly it sped up learning (decreases in costs due to experience or scale). In solving this market catalyst problem in the short term, governments left the door open in the long-term for gaming the system if and when solar prices (really LCOE) started to dip well under the FIT rates. And that is precisely what has started to happen. The bull rush to obtain legacy FIT program rates once technology costs plummeted has fueled a massive boom in solar. On the the surface, this seems like a great problem to have. More solar! But, this is a case of too much too soon, and governments are responding by pulling back on their FIT programs and leaving a wake of solar developers scrambling to make their projects pencil. Source: GTM Research The European renewable miracle has been taking some nasty hits lately. Even the energy transition darling, Germany, has not been immune to the pervasive bust cycle that is spreading across the continent. What changed so quickly, you may ask? Well, it is the classic story of a good thing gone bad. The FIT programs that accelerated solar adoption so quickly in years past are now becoming the victim of their own success. Where they erred was in making the terms so enticing for so long that they ended up overheating the solar market. There is a delicate balance between creating an incentive to attract risk-taking early adopters and reducing or retracting the incentive once the economics of the market support broad participation. Or, in other words, they just let too many players at the table, and this time, the cards were stacked against the house. Governments underestimated the speed at which solar prices would fall, which left them in the undesirable position of having already committed to paying well above market prices. It was boom times for the solar industry, but it could not last. The graphs above look like tulip mania (if this reference eludes you, please read for some amazing dinner table chatter) for crying out loud. Germany had three years of putting over 8 GW online. Italy spiked in 2011 with nearly 10 GW of solar, only to plummet to under half of that in the following year. The UK has witnessed a remarkable growth in solar, only to cut the FIT program by 65% in one fell swoop. Similar patterns were seen in many other EU countries. And let’s not forget Japan, whose boom-bust cycle dwarfs those of all of the ill-fated EU countries already mentioned. Japan is still in the top 3 globally in terms of annual solar capacity installed, but is headed for a protracted decline in solar over the years to come, again due to an over-aggressive FIT program. But FIT programs are so simple and elegant. What alternatives exist, you may ask? Source: GTM Research Letting go of a good thing is hard, especially for an industry like solar that may suffer from a tinge of PTSD from the head-spinning boom-bust cycles of the past decades.
After all, with the FIT structure solar did not necessarily have to directly compete with other generation technologies. A decade ago, that was just fine because solar would not have been competitive. Solar needed an incubation period to slide down the learning curve to lower, more competitive prices and meaningful deployment scale. Now that solar can tout itself as being one of the most cost effective electric generation technologies out there, there needs to be an increasing willingness to actually compete in markets with other generation technologies. Latin America has started to buck the FIT model in favor of an auction process in which solar competes with other generation technologies, both from independent power producers and incumbent utilities. This has helped feed a boom in Latin American solar, as it turns out that solar can beat out nearly all other generation technologies on a pure LCOE basis. Nearly three quarters of new capacity additions in Mexico will come from solar, easily more than 1 GW. Brazil is in the same league. And various EU countries and India are also doubling down on auctions. But, auctions are not a panacea. We have all seen auctions in the movies, and the meme of the irrationally exuberant bidder going well beyond their true willingness (or ability) to pay in order to secure the prize. While we all hope that power producers are somewhat more measured and rational in their approach to bidding in these markets, there remains the possibility that competing in auctions may drive prices down quickly to unsustainable (even unprofitable) levels. In fact, some early evidence in the auction tea leaves is that even these markets can overheat as bidders aggressively pursue market share. On the one hand, it may be good for business in the short-run, and auctions may effectively accelerate learning and cost reductions. But, on the other hand, auctions run wild may undermine the long-term viability of the ecosystem of power producers feverishly competing to keep up with the Joneses to survive. Exuberant bidding to support short-term growth is not a phenomenon that should feel altogether unfamiliar, as it is precisely what drove SunEdison to bankruptcy. Further reading: As Feed-In Tariffs Wane, Auctions Are Enabling the Next Wave of Solar Cost ImprovementsFeed-in Tariff: A policy tool for encouraging the deployment of renewable energy technologiesInnovative Feed-in Tariff Policy Designs that Limit Policy Costs A Policymaker’s Guide to Feed-in Tariff Policy DesignFeed-in Tariff Policy: Design, Implementation, and RPS Policy Interactions Annual U.S. Energy Storage Deployments, 2012-2020E Can somebody throw the energy storage industry a bone? It is a little known fact that the investment tax credit (ITC) was a key catalyst for the emergence of solar as an essential component of the future electric grid. Well, not really. That statement borders on platitudinous. It should be no surprise, then, that the energy storage industry is angling for similar treatment by the almighty tax deities at the IRS. Energy storage, after all, is touted as being a key enabler of high levels of renewable energy penetration. Handcuffing energy storage will only undermine the grid integration of solar and wind down the line. So, can the energy storage industry get a bone here? Yes, it is a relatively nascent industry (at least in battery technology) undergoing a rapid period of technological learning and experimentation. But out of the frey, we are starting to see some dominant technologies and applications emerge within functional markets. While lithium ion batteries are the current industry darling, there are many other viable storage technologies including stored hydropower, which still dominates the energy storage field overall. In the periphery, there are a host of other storage technologies incubating in R&D facilities, start-up companies, and corporate technology giants. Perhaps in response to the eventuality of energy storage becoming a key component of the electric grid, the IRS threw the energy storage industry a bone, but it came with some strings attached. Energy storage already qualifies for the ITC, right? Yes and no. Yes, energy storage already qualifies for the ITC, but no, it is does not qualify under all circumstances. Energy storage that is powered by solar or wind qualifies for the ITC, though with some caveats related to the extent to which grid electricity is also used to charge the energy storage system. This is where things get a little tricky. Assume that you have an off-the-grid solar + storage facility (a grid defector!). Simple - the ITC applies, and you can get on with your homesteading. But for all grid-connected systems, there is an upper limit to how much charging your storage system can receive from the grid and still qualify for the ITC. That magic number happens to be 25%, meaning that a whopping 75% of energy storage charging needs to come from solar. That is just the minimum standard for qualifying for the ITC. The full ITC benefit is reduced in proportion to the amount of energy input coming from the grid, so anything less than an energy storage system charged by 100% solar will receive less than the full ITC benefit. Add to string the fact that solar + storage projects are benchmarked to the first year’s solar power output for the subsequent four years of the tax benefit, which means that any reduction in solar output will be penalized with a lower ITC benefit. And all of this was articulated in a private letter, which does technically establish a precedent, but is a somewhat opaque way to communicate what could be a substantial benefit to the energy storage industry. See here for a clever dive into the details of solar + storage. Stand-alone energy storage ready for an ITC vaccination It is clear that coupling solar (or wind) with energy storage is a good idea, and will be done with increasing frequency over time. It is also clear that energy storage will not and should not be relegated to the sidelines of the ITC prom waiting for some attention from the solar and wind dancers on the floor. In fact, it is imperative that energy storage be granted a clear and clean invitation to the ITC prom independent of their relationship to solar and wind, when and where appropriate. If the aim is to reduce barriers to more energy storage development providing flexibility and ancillary services to the grid, then there is a pretty obvious argument to be made about the need for a little ITC vaccine for stand-alone energy storage. Why a vaccination? Well, energy storage, like many emerging clean energy and smart grid technologies, could benefit from an inoculation against investor skepticism. There is no shortage of bullish projections about the future of energy storage, yet many project developers find themselves searching for capital. Even when they land upon a willing investor, their investment often comes with a heavy cost of capital penalty due to the perceived risks and uncertainties associated with energy storage projects. Not unjustified on the part of the savvy investor in search of those ever elusive risk-adjusted returns. But also not the formula for ramping up energy storage deployment, which, after all, is the key to sussing out technologies, business models, and financing structures. Learning, in other words, which is exactly what the ITC has been doing solar all of these years. Roping in stand-alone energy storage projects into the ITC framework could be just what can get investors over the hump of really going gangbusters on energy storage. SolarCity Residual Cash Flows (Source: SolarCity) SolarCity is still the prettiest girl at the dance SolarCity is without a doubt the most trend-setting solar finance company on the planet. They are a vertically-integrated, distributed solar superpower that seems to grab newsworthy headlines on a weekly, sometimes even daily basis. On April 6th, SolarCity announced a $150 million non-recourse financing facility with Credit Suisse to support the deployment of new commercial PV and energy storage assets. The very next day, the company announced a tax equity closing of $188 million from Bank of America Merrill Lynch for residential solar deployment. At first glance, that amount of activity could worry investors that SolarCity is pursuing too many verticals in parallel without focusing efforts on the most profitable segments. This type of investor sentiment is currently relevant considering that the mainstream explanation for SunEdison’s bankruptcy is simply that the company took on too much debt while drinking water from several different fire hoses. I would argue that SolarCity is similarly extended in terms of asset classes, but they have been consistently more savvy than SunEdison in regards to monetization. Unlike SunEdison, SolarCity has maintained a focus on creative financial engineering that produces near-term cash flows to sustain the upfront capital outlays required by today’s solar finance institutions. John Hancock to the rescue? On May 4th, SolarCity completed a $227 million “cash equity” financing with John Hancock Financial for approximately 200 MW of operating solar projects. This transaction serves as the most recent example of SolarCity monetizing the underlying cash flows associated with the company’s long-term power purchase agreements with individual off-takers. Unlike the two transactions in April, John Hancock’s injection is not a critical component of the capital stack to initially finance the development and construction of solar projects. This cash equity transaction is regarding solar assets already in operation, across three segments (residential, commercial, industrial), and spread between 18 U.S. states. Within this portfolio, the average FICO score for residential customers is 744, and most of the commercial off-takers are national retailers. News flash: large institutional investor is attracted to diversified portfolio with virtually no risks. Which begs the question, why did SolarCity take a discount on future cash flows and sell now? Just like every other solar company in the 3rd party ownership space, SolarCity is bleeding cash due to the high customer acquisition costs and needs to display short-term revenue to keep shareholders confident in the company’s long-term value proposition as a distributed power provider. See here for a current perspective of the 3rd party ownership climate in the U.S. Despite the success of matching low-risk solar PPA payments with an institution that is all too familiar with generic annuities, SolarCity now has some longer term expense considerations to overcome. They are still responsible for the O&M expenses related to servicing the 200 MW of assets, and they’re responsible for expenses related to decommissioning the PV systems if the PPA term is not extended. As part of the cash equity transaction, SolarCity retains the rights to 99% of the post-PPA cash flows, but it's anyone’s guess how likely it is that post-PPA revenue streams will be realized. Although this transaction structure is new and newsworthy, it’s just another tool in the solar finance industry’s toolbox to monetize future cash flows. SolarCity Cash Flows (Source: SolarCity)
The jury is still out on whether solar and securitization are a match made in heaven Asset-backed securities have a negative connotation to the layperson, to say the least. But there’s no denying that securitization can play an important role in increasing investor access to specific asset classes, as well as raising affordable sources of financing in capital intensive industries, like solar energy. The key word here is affordable. SolarCity has now sold six tranches of solar-backed securities over the last 30 months, including $49 million on March 1st when the weighted interest rate was almost two percentage points higher than a sale just 12 months earlier. The rise in SolarCity’s cost of capital is troublesome and may cause the company to abandon the new strategy and seek out alternative forms of financing. It’s clear that the 'SunEdison effect’ is having a real impact on investor comfort with the reliability of long-term solar contracts, despite the incredibly low default rates experienced by SolarCity (and others) to date. As long as default rates remain very low and companies continue to drive down the cost of customer acquisition, the opportunity to sell the underlying cash flows of solar projects will remain for both public and private developers. (Source: GreenTech Media)
Everyone likes lists. Lists are candy for our mind. Give me a Top 10…, and my mind naturally embraces the elegant hierarchy, 1 better than 2, and way better than 10. A simple rubric for a messy world. So, it was with some curiosity that I digested Ernst & Young’s Renewable Energy Country Attractiveness Index. See renewable energy is complex, and lists are simple, so this makes a good pairing. Like red wine (complex, hence - see, swirl, smell, sip, savor) and chocolate (simply delicious). What do we find? Clearly, United States #1! As if… The BICS - Brazil, India, China, South Africa (sorry Russia) - are all in the Top 11 and are the big upward movers. Just fascinating considering the sheer scale and dynamism of those economies. Latin America is on the rise with Chile, Argentina, and Mexico all in the Top 20 (and Summer Olympics in Rio!). And Europe is increasingly looking like a basket case. Germany, France, United Kingdom, Netherlands, and Belgium all dropped spots. Regrettably, some petulant factions within the EU are backpedaling on much of the industry-paving progress of the previous decades. What a mess. Sophisticated European investors will likely migrate into international renewable markets. After all, a 4% unlevered IRR is not going to winning any beauty contests. The ascendant BICS and Latin American countries are the investor darlings of the moment. But the renewables investment landscape is not as simple as that. For this, we another list! The Venture Capital & Private Equity Country Attractiveness Indexmeasures the...well, it basically says it in the title. Rest assured, United States #1! As if… But some mind-tickling asymmetries arise between these two lists. Ahhh -- when lists tell contradictory stories, it makes us to have think! Some countries have an attractive investment environment for renewable energy but an overall weak (or altogether suspect) environment for VC/PE investors. Take, for instance, Argentina. 18th for renewable energy investing, but a lowly 64th for VC/PE investing. Lest we forget - the economic scene in Argentina can get a little wobbly at times. A similar pattern holds for South Africa, Brazil, Morocco, Egypt, and others. All great places for renewables, but a little shaky for investment in general. So, I leave you with the holy grail concept of risk-adjusted returns. How might you adjust returns to account for risk? Well, that is more of an art than a science. No simple list can tell that story. Last year, IronOak Energy’s investment advisory practice had some challenges competing against yieldcos on behalf of our solar investor partners.
We kept abreast of the yieldco’s up/down trends at IronOak’s stock chart. They were offering what some called “a stupid low” cost of capital. That was sometimes said as a judgment on the the yieldco business model. Other times it was a said with a slight jealousy: “I wish our yields were still attractive at those levels so we could win more deals with predictable long-term cash flows.” Developers licked their lips. Those low-yield requirements made their discounted cash flow models really sing. As we all know, in late summer last year, both developers and yieldcos bought their share of Kleenex boxes. But this was great news for private equity and helped improve their returns. Many claimed the model was broken. We thought that was shortsighted. Sometimes innovators hit a speedbump, but then they hit the accelerator again. Now several yieldcos are getting ready to go to public markets. It’s not time for them to be big-time project buyers at attractive costs, but that time will come. For now, private equity still rules. Everybody loves solar. Well, except for those who think solar panels cause cancer and prevent plant photosynthesis. (Seriously. Summary here.) But we digress… Solar projects makes for great headlines, company brochures, and dinner party conversation. But are these good infrastructure investments? (Let’s keep investments in companies separate for now. Venture capital and public equities are very, very different beasts.) If you ask Warren Buffett, he has already answered, with more than $15B invested in solar (and wind) projects. I hear that he’s a pretty good investor, so that says something. And if you look at the two graphs below, then you should agree that the market is trending up. Predictable markets, especially at the utility scale, with 5-year projected growth of 1.9x versus 2015. Residential solar also looks strong at 2.1x growth over the same period. However, commercial and industrial markets may only increase about 1.3x, with one-off credit risks that challenge scaling. So, go long on U.S. solar, right? Broadly, yes, but the devil is in the details. Picking the right market, site, developer, offtaker, and finance model will, of course, make or break the deal. And these are just U.S.-specific projections. The world is a big place. Now let’s look at other countries’ experience. Summary: It’s not predictable year-over-year growth for many years. The graph below tells a different story: Solar project investments are better defined as taking a ride screaming with joy and pain on the “solar coaster.” So, short solar markets in certain countries? Well, maybe, though not technically easy to do since this is mostly private, not public, equity. In summary, should you go long or short on solar infrastructure? Um...yes, let’s grab a beer and talk in more detail. States Authorizing 3rd Party Power Purchase Agreements (Source: DSIRE) First, the bad news: policy battles over 3rd party ownership of solar muddy the waters Just pile it on top of the other cadre of unenlightened policies that North Carolina is behind these days. Yes, North Carolina, my home state, is making headlines for another boneheaded public policy move, this time regarding the highly controversial topic of… solar! The NC Utility Commission (NCUC) recently upheld a law that prevents 3rd party ownership of solar projects. The case that brought the issue into the public limelight concerned a whopping 5.25 kW installation that the environmental advocacy group NC WARN had built to provide electricity to a local church. The two parties signed a 3-year PPA at a discounted rate, which, doing some quick math, might have provided around 23,000 kWh per year valued at around $4,000 or so for the life of the PPA based on prevailing rates. Well, Duke Energy was not having it! The biggest utility in the nation, valued at over $55 billion, opposed NCUC and beat down this encroachment on their business. And just to make an example out of NC WARN, they were slapped a $60,000 fine, which is around 15x more than the electricity that would have been sold in the PPA arrangement. Duke Energy is not entirely foolish to help combat the proliferation of 3rd party ownership, but their choice to do so goes against the countervailing inertia moving us into a more distributed energy future. Duke Energy will surely be fighting an uphill battle on this issues for years to come. North Carolina is not alone in this business of prohibiting 3rd party ownership of solar projects. The state stands in solidarity with Florida, Kentucky, and Oklahoma, which sounds like a NCAA Final Four (pause for sad memories of UNC’s recent loss). Unfortunately, that is where the commonalities stop, because, in the case of solar, competition (in this case with incumbent utilities) is prohibited. The game is rigged in favor of utilities with virtual, if not actual, monopoly power, something that supposedly goes against federal trust law. As a North Carolinian, it is with deep regret that I admit that South Carolina (!) recently passed legislation to allow for 3rd party ownership of solar projects. Georgia has done the same (although not accounted for in the map above). So, take heed, NCUC, your neighbors to the south are upstaging you on the transition to clean energy. Well done. Just add it to the list... On a positive note, 3rd party ownership trends are helping to unlock potential in the behind-the-meter corporate solar market Commercial PV Installations by Ownership Structure (Source: GreenTech Media)
With all of the pushback on 3rd party ownership of solar in certain states, one has to consider what might happen if this was allowed. Well, one thing is for certain - corporations would be buying into solar, and likely in a big way. This is, after all, the situation that we see in states that allow 3rd parties to sell electricity from solar projects to corporations. As solar has become more competitive with prevailing retail electricity rates, corporations have started to see locking in stable electricity prices from solar as a complete OpEx no-brainer. Though a handful of corporations opt for the direct ownership and financing approach, the vast majority are seeking 3rd party owners to provide them with solar solutions. And those trends are expected to continue, as shown in the projections above. I go into further detail on this topic in a previous blog. So, what is to like and dislike about this arrangement? One the one hand, 3rd party ownership does fundamentally decentralize the electricity provision business, especially as behind-the-meter applications become more reliable and cost-effective. That is seen as a threat to incumbent utilities who have historically been the end-all-be-all of power provision. Setting aside utility concerns for revenue loss, the real question is whether utilities can meet the needs of large offtakers looking for distributed power solutions. The answer is yes and no, depending on the utility. It seems like 3rd party solar ownership is here to stay, so what’s the catch? This gap in the market opened the door for an explosion of independent power producers, offering a staggering array of behind-the-meter solutions to customers. Some of these we have come to know well - SolarCity, SunRun, Vivint, etc. But there are many others vying for a place near the top of the pecking order. So, what of the risk of working with these solar companies? It really boils down to counterparty risk. Two parties really have to believe that each other will continue to exist as solvent enterprises for decades to come. Not a trivial proposition from the standpoint of a corporation analyzing the evolution of the solar industry, perhaps for the first time. Clearly, the ongoing tumult of the growing solar industry (aaahh SunEdison chuuu) brings to light the sometimes ugly process of picking winners and losers. It would not be unreasonable to assume that the landscape of solar companies out there will continue to change for some years to come. So, why should you sign a decades-long PPA with a company that may not continue to exist for the next five years? That is the question of the moment. But if the data are any indication, corporations are becoming increasingly comfortable with signing long-term PPAs with 3rd party solar power producers, not to mention homeowners. So, back to the original story, what are the NCUC and Duke Energy, in a classic “tail wagging the dog” relationship, so worried about? It might be the “adapt or die” mantra that has been reverberating around the industry since the collapse of several European utility titans. But rather than adapting, they are digging in their heels on an issue that 46 other states in the U.S. have already come to an agreement on. If there is anything that we can agree about the future, it is that change will be ever present. 4/30/2016 It’s the offtaker, stupid! What we should have known from the start about community solarRead Now What’s new? As many have predicted, community solar continues its nationwide growth. We previously discussed the fourteen states that have adopted specific enabling legislation for community solar. With the growth in business potential, more and more states are working to adopt or revise policies to accommodate this new model for distributed energy generation. According to the NC Clean Technology Center, in Q1 2016, seven states have considered, amended or clarified rules governing community solar programs; and in states that are slow to respond, utilities are taking the lead, submitting proposals for community solar programs without a specific enabling legislative framework in place. According to SEPA’s recently released report, “Community Solar: Program Design Models,” there were 68 active programs in 23 states in the summer of 2015, with many more programs being planned. Geographic Distribution of Community Solar Projects (Source: SEPA) In New York, EnterSolar started construction of the first community solar project in the state. Relatively small in terms of capacity (less than 1 MW), the project is developed under New York’s first phase for community solar development that limits development to areas with the highest grid locational benefits and to low-income communities. This month New York enters the second phase of the program that allows for full implementation of net metered community solar projects across the state. Many developers are already working hard to secure development contracts, and even the city of New York has introduced a municipal plan to promote community solar developments within city neighborhoods. What’s wrong? Nothing is wrong with community solar. On the contrary, we think that community solar is awesome. However, despite its great potential to unlock solar energy to more than half of electric consumers in the U.S., and although it is gaining traction nationwide, development rates for community solar are nevertheless 20% lower than expected. Even in states that have addressed management structure and regulatory uncertainty concerns projects are still not springing up as one would have expected. So what is it? Why aren’t we seeing more community solar projects? It’s the offtaker, stupid! The reality on the ground is that developers and utilities are still struggling with selling community solar to customers. Relatively complex in structure and less known than other models of distributed solar generation, community solar is a hard sale. Customers are wary of entering into unfamiliar financial adventures involving multiple parties, especially when the transaction involves an upfront investment as is the case with most community solar schemes. Part of the challenge lies with the fact that customer attitudes to community solar vary. While some programs are fully subscribed and thriving, others are underachieving. Many have tried to identify the winning set of program features that makes a community solar project appealing, but because regulatory frameworks, transaction structure, and management schemes vary greatly from one project to another, identifying best practices from existing projects has proved to be an elusive task. However, a recent study conducted by Pacific Consulting Group, might have finally revealed the answer to the question of what makes a community solar project successful. Taking a creative approach to solving a persistent problem, PCG focused on customers instead of projects. PCG conducted a market survey among potential offtakers in eight community solar states, asking respondents questions aimed at identifying how market acceptance of community solar changes with project features. Unsurprisingly, the number one factor in customer acceptance is initial investment; projects that do not include an initial investment or require only a small upfront investment are highly valued. The second is percentage of electricity bill to be covered by the investment; the lower the percentage of the bill covered, the less attractive is the project. Together, the two attributes account for 20% of total importance. Other interesting findings are that customers value savings five years out as more important than immediate savings (suggesting that customers are not intimidated by the long-term commitment associated with community solar), customers are largely indifferent to what they lease or own, and are not persuaded by incentives other than the potential payback (e.g., late fee forgiveness). Relative Importance of Seven Program Attribute on the Decision to Adopt Community Solar (Sources: PCG; SEPA)
The study also measured customer responsiveness to marketing approaches and revealed interesting trends among communities. The most important findings are that messages emphasizing customer ownership and individual economic gains resonate better than messages emphasizing conservation or “green” considerations. Utilities, nonprofits, and solar organizations enjoy better credibility and therefore have better prospects in influencing potential customers than other entities or individuals (indicating the value of business partnerships). Also, personal messages targeting individual customers are more effective than mass media (with a message on the utility bill being the most effective form of customer engagement). All I want is peace of mind Understanding how to approach customers and how to tailor transactions in a manner that is appealing to potential offtakers is very important for the continued growth of community solar, but it is not enough. Even after we have addressed project features, payout structure, and marketing strategies, we still need to find an entity that will manage the project once it is operational, and long-term management of multi-party endeavors is costly. Some states have tried to address this concern by introducing an intermediary special purpose entity responsible for aggregating membership interests and managing the relationship with the local utility. But the question of cost and management remained largely unanswered, at least until now. Responding to market needs, community solar management firms are emerging. Firms like Clean Energy Collective offer management platforms that ease operations, reduce costs, and give offtakers, investors, and utilities exactly what they need - peace of mind. Institutional investors have been reluctant to invest in solar, until now Perceived risks have long dissuaded institutional investors from venturing too deep into solar investments. Fortunately, perceptions can change. Whereas once the solar industry was hampered by the perception that technology was risky, markets were untested, and policy uncertain, now the solar industry is increasingly seen as a low-risk infrastructure investment that is increasingly enticing for the less risk tolerant institutional investors out there. Asset Financing for New-Build Renewable Energy Assets ($B) To be sure, the solar investment space is pulling in interest from institutional investors, but it is also being pushed out of many fixed income and treasury investments due to the extended period of low interest rates.
Now that those “risk-free” assets are now also return-free, investors are anxious to explore investments with stable and predictable yields, ideally that generate free cash flows. As solar performs more like an infrastructure investment, with contracted cash flows, predictable technology, and a very long runway of future demand, interest from institutional investors is piquing. The question is - can solar meet the scale and risk-return profiles that institutional investors require? Can clean energy projects match the capital and risk profiles to entice investment? There are many ways that institutional investors may want to increase their allocation in clean energy - green bonds, low-carbon investment funds, etc. — but here I am going to focus on direct investments in projects. Over the last decade, the solar industry has expanded into a highly diffused ecosystem comprised of a large range of developers, EPCs, OEMs (though many fewer of these), and financiers. On the financing side, the availability of debt and tax equity has been a key driver of where and what type of projects could be built, and sponsor equity providers have come in as the final layer of the capital stack. Many solar projects with stable cash flows for 15-20 years and limited construction risk can yield returns of 10% or more, which easily beats the returns that can be achieved in the bond market. To really catch the eye of an institutional investor, portfolio sizes need to be in the $100s of millions, ideally yielding unlevered returns of 8% or more. Though large scale projects and bigger portfolios of projects have started to come through the pipeline, it is still difficult for a single developer to create an investment opportunity of the scale and risk profile that serves the needs of institutional investors. Even when these investment opportunities exist, institutional investors are wary of direct investments that expose them to illiquidity or diversification risk. Because of this, much of institutional investment to date has been in providing debt restructuring or acquiring an equity stake in operating assets, as most investors do not want to take on development risk. This is changing, but this mismatch remains an obstacle for moving beyond opportunistic engagement with institutional investors. As a result, some funds specializing in clean energy and low carbon infrastructure investment have emerged to act as stewards of institutional dollars. But will this be enough to really jumpstart institutional investment into solar projects? Asset-backed securities hold the key to bringing institutional investors on board In reality, institutional funds are not going to become big players until a market emerges that can bundle clean energy projects into securities and match institutional investor appetite. And given the predictable cash flows generated by solar projects with long-term PPAs interconnected in stable markets, these projects may actually lend themselves well to forming relatively low-risk, transparent, cash-generating securities. The key here boils down to risk mitigation. When a portfolio of solar project cash flows are pooled into one fund, that fund serves to protect the investor from the developer/sponsor’s corporate risk, which allows for standardized securities to be issued against the capital in that pool. Then, investors have a tradable security through which to commit capital to solar infrastructure investment. If these securities are well received in the market, they can create a virtuous cycle of demand-pull for the underlying asset, in this case solar. Beware: this virtuous cycle also occurred for the housing industry in response to mortgage-backed securities, so this positive feedback can have distortionary impacts on the market as well. At least presently, the solar industry does not seem to invite the same overzealous market speculation that threw the housing industry into a downward spiral. So, are we seeing the emergence of clean energy-backed securities to help leverage institutional investor capital? To some degree, the answer is yes. We can see this primarily in the rise of the green bond market. Bonds as a debt instrument, generate a contracted cash flow, which can back a security. The global green bond market grew to over $40B in 2015, a portion of which was asset-backed securities used to finance aggregate portfolios of smaller debt facilities into institutional investor-sized offerings. But there is a lot of work to do on expanding clean energy finance beyond the bond market. So, keep a lookout for innovations in solar securitization, as it holds the key to attracting institutional investors. Related data points:
Further reading:
In our previous monthly reports we have focused on state solar policies. Our research indicated a growing trend among state legislators and regulators to review, amend, and in several cases, phase out or even cancel solar incentives and long-standing, proven solar policies. Although this process could be viewed as a natural regulatory action in response to a market reaching maturity, it has nonetheless taken its toll on the solar market. After the Nevada Public Utility Commission’s controversial December 2015 decision to slash net energy metering, many residential solar installation companies halted operations in Nevada, with giants like SolarCity and Sunrun exiting the state. Similarly, Michigan’s legislature is considering a change to its solar policy that will reimburse generators at wholesale rather than retail rate, making the state’s thriving solar industry nervous. In February, Massachusetts reached its net metering and REC caps, halting operations of solar developers and installers in a state that has more solar jobs than any other state except California. And North Carolina’s lucrative solar tax credit is set to expire at the end of this year, creating uncertainty and concern among local industry players in one of the nation's largest solar markets. Policy uncertainty is never a good thing. However, what many state-level regulators and legislators tend to forget is that keeping policies unchanged is not enough; to continue to grow, the solar industry needs certainty as much as it needs stability. In a constantly changing regulatory environment, threats are almost as much of a problem as actual changes. Initiatives to review or amend policies, increase rates, or decrease incentives make investors wary of new investments, thereby escalating the cost of raising capital. Thus, while DC legislators have contributed their share to the national effort to create certainty and stability in the solar market, state legislators are failing to do their part. This is rather sad news for the solar industry that celebrated the ITC extension, but relies on states’ policies to continue driving investments in solar energy. Indeed, renewable portfolio standards account for more than 50% of investments in utility solar, and net energy metering is considered the main driving force behind residential rooftop solar. However, it is not all grim for the solar industry. Despite the uncertainties from state to state, the industry continues to grow. The quarterly SEIA/GTM Research U.S. Solar Market Insight report for Q4 2015, released in early March, predicts that the solar market will grow 119% in 2016. As in previous years, most of the projected added capacity is attributed to utility scale installations. But if many states are not providing the stable regulatory framework required for a healthy business environment, where is this substantial projected growth in utility scale solar coming from? Before Congress extended the ITC, the 30% tax benefit for solar installations was set to drop to 10% on January 1, 2017, and to expire in 2018. This tax cliff created an incentive to bring as many projects as possible online before the 2017 drop down, thus driving the unprecedented expected growth in 2016. Utility scale installations require long planning and development, so although the ITC was extended last year, it was too late for players to react to the new tax environment. This is why installations in 2017 are expected to fall significantly, while commercial and residential PV will be less affected. The effect of the ITC extension on the different solar sectors can be seen in the graph below. U.S. PV Installations With and Without ITC Extension, 2010-2020 (Source: GTM Research) Moreover, there is another federal framework that drives investments in utility scale solar. Unbeknownst to many, the federal Public Utility Regulatory Policies Act of 1978 (PURPA) is gradually emerging as a useful tool for utility scale developers in a post-RPS world. Enacted in response to the 1973 energy crisis, PURPA imposes a mandatory obligation on utilities to purchase renewable energy from “Qualified Facilities” (QF) at the utility’s avoided cost. To meet the requirements for a QF, an energy-generating facility must not exceed 80 MW and its primary energy source must be biomass, waste, geothermal, or renewable resources. With prices per megawatt-hour in the $40 to $60 range, utility solar is at cost parity with natural gas, making it a strong competitor in PURPA’s avoided cost markets. In 2015 over 500 MW of PURPA-driven projects came online in North Carolina, and states like Texas, South Carolina, Utah, Oregon, and Idaho are also leading the way in utilizing PURPA for utility scale solar. States With >50 MWdc Non-RPS Utility PV in Development (Source: GTM Research)
As a federally mandated purchase, PURPA solar projects are not subject to state solar caps. Moreover, FERC regulations define “avoided cost” as the incremental costs to an electric utility of electric energy, capacity, and environmental externalities fees which the utility will incur if not purchasing electricity from the QF. The broad definition of “avoided cost” allows more facilities to enjoy QF status. However, despite the seemingly positive outlook for PURPA’s potential for solar developers, one must remember that it is very hard to enforce a PPA on a utility that does not want to enter one. One way of deterring QF developers from engaging with uninterested utilities is to propose terms and conditions that are more onerous to the QF than to non-PURPA counterparties. While FERC has succeeded at curtailing such practices, bad faith negotiation tactics are hard to prove and only few developers are willing to pursue costly litigation in an effort to obtain a PPA with an obstinate utility. To reduce transaction costs and assist smaller developers in negotiating with utilities, certain states have adopted standard contract rates for QFs of up to 10 MW (California up to 20). The standard contract makes it nearly impossible for utilities to avoid purchasing electricity from QFs. It is therefore not surprising that utilities in leading solar PURPA states are requesting utility commissions to reduce standard rates contracts caps. Late in March, the Oregon PUC approved Pacific Power’s request to reduce the eligibility cap for solar generation at QFs to three from ten MW, and a similar motion by Duke Energy was rejected by the North Carolina PUC late last year. As the price for solar generation continues to drop, we are expecting to see more PURPA driven PPAs across the nation. Whether PURPA PPAs will provide the necessary certainty and stability the market is currently lacking depends on FERC’s willingness to enforce its rules on avoided cost mandatory purchases, and Public Utility Commissions’ ability to withstand utility pressure to reduce standard contracts rates caps. 3/30/2016 What future Value of Solar policies could mean for the solar industry: 3 key things to knowRead Now There has been a wave of contentious net metering policy battles waged across the U.S. in 2016. Some net metering policies have remained largely intact, as in California, though much to the chagrin of the utilities. Other net metering policies, such as those in Nevada, have been fundamentally restructured, to put it kindly - though many would say they were just plain gutted. As with the ITC, a significant part of the solar industry formed around the net metering policy structure, and like many industries is reluctant to let go of such a foundational policy. But the aforementioned battles beg the question - is net metering the appropriate policy for solar looking to the future? Many believe that it has been a necessary stopgap policy measure, but not one that needs to live in perpetuity. One alternative that has been floated is the idea of a Value of Solar (VOS) policy that seeks to compensate solar based on a more nuanced understanding of the value that it provides to the grid. That is an easy enough idea to get behind, in theory, but just what could VOS mean for the industry? (Source: Institute for Local Self-Reliance)
Utilities and solar investors both come out on top with a VOS policy
Avoided costs hold the key to understanding how the “Value of Solar” is framed
Playing up the environmental costs angle could be the greatest strength of VOS
The City of Austin, TX and the State of Minnesota have led the charge on the initial VOS studies, and have proposed different cost structures and calculation methodologies. It would have been easy to anticipate that VOS would have taken off, especially as a substitute for the much-maligned net metering policies, but so far it has not. But if the recent solar policy battles are any indication, the days of the old net metering policies may be numbered. VOS may open the door for a more nuanced treatment of solar in our energy policy. States with > 50 MW Non-RPS Utility PV in Development (Source: GreenTech Media)
Related data points:
Conventional wisdom says that the solar market is policy-driven, but this is changing in a big way The most vibrant and active solar markets are driven by Renewable Portfolio Standard (RPS) programs with supporting net metering and feed-in-tariff (FIT) programs, or so goes the conventional wisdom. California and Massachusetts exemplify this supposition, as their RPS programs undergird two of the largest utility-scale solar markets in the U.S. But evidence is mounting that the solar market will no longer be driven exclusively by RPS mechanisms. In 2015, 39% of utility-scale solar was procured using non-RPS mechanisms, and this is projected to increase to 52% in 2016. This begs the question - what is driving this marked shift? Falling costs are making solar more competitive with conventional generation The fact that solar has been undergoing rapid cost reductions is a borderline platitude at this point (see here for a good summary of key facts). Estimates for the average installed cost of utility-scale solar in the U.S. was $1.45/watt in 2015, with more reductions projected in the coming years. However, the real interesting question is how these cost reductions are changing the dynamics of competition across energy sources for utilities. Grid parity is considered the holy grail for utility-scale solar, and grid parity (or better) with prevailing natural gas prices has become a reality in many U.S. states (see here for some more detail on grid parity). This change in the market is making it real easy for utilities to make the simple economic argument that signing 20-year PPAs at below $60/MWh is not only the most prudent course of action from a bottom-line perspective, but also the best hedging strategy, which is discussed further below. This has also given rise to a new wave of avoided-cost contracts in states where solar is cheaper than conventional alternatives. This was enabled by PURPA (Public Utility Regulatory Policy Act), a landmark energy law from the 1970s that mandates that utilities purchase electricity from independent power producers (IPPs) if their cost is below the marginal cost of increasing the utility’s generation capacity through conventional means. This type of arrangement greatly reduces the risk of developing solar projects of a certain size, and has fueled the markets in states such as North Carolina. There is another big story behind the rise of non-RPS utility-scale solar related to the role of corporate PPAs, which you can dig into in a previous blog. The hedge against variable (and volatile) natural gas and coal fuel costs is attractive Many utilities are starting to see the writing on the wall in terms of their exposure to variable and volatile fossil fuel prices. Do not believe the hyperbole that oil and gas prices have reached a “new normal” with prices hitting lows not seen for many years (see a good discussion of peak oil here). We are likely amid an anomalous period of low petroleum prices brought on by a confluence of factors - namely, historically high oil prices prior to the 2008 recession which escalated investment in exploration, and cheap financing made available through low interest rates. The current oil and gas low prices are undercutting the ability of firms to invest in exploration, which will eventually erode the current surplus and lead to future deficits and much higher prices than we see today. As discussed in a previous blog, even the most conservative projections of future natural gas prices has them increasing, with many projections substantially above current prices. The future of coal is a more complicated matter, but suffice it to say that any utility which maintains coal as a primary long-term energy procurement strategy will be taking on a great deal of policy and financial risk. When seen from this perspective, any rational observer of the U.S. utility sector would naturally conclude that they need to invest heavily in hedge strategies to protect against the inevitability of volatile and unpredictable fossil fuel prices. As many utilities have gained exposure to and comfort with solar PPAs as a compliance mechanism to meet RPS targets, it started to dawn on them that there could be substantial benefits to using PPAs as a hedging strategy. As a consequence, we are now witnessing a boom of procurement taking place outside of the RPS-driven solar markets, at least partially driven by the desire to increase their portfolio of low-risk electricity generation from solar PPAs with predictable rates for 10-25 years. It seems somehow fitting that utilities are increasingly more willing to exchange their variable-priced fossil fuel capacity for variable-generation solar capacity. Further reading:
C&I solar market starting to attract some attention from investors
Commercial and industrial (C&I) solar has, to a certain degree, fallen between the cracks in the landscape of solar financing. Utility-scale solar, given its high capital requirements and relatively straightforward risk profile, has been an easy sell for debt providers, tax equity investors, and well-capitalized equity investors. Small-scale rooftop solar has found success in third-party financing and leasing models that have unlocked a wave of deployment, especially in states with favorable net metering policies. Compared to these two markets, C&I has been a more difficult market to serve. The smaller scale of the projects is often unattractive to many investors, and can create a bottleneck when it comes to finding tax equity investors. Moreover, the higher transactions costs and more opaque risk profile compared to utility-scale solar have handicapped this sector in the eyes of many underwriters and investors. The challenges faced by the C&I market are not evidence of any underlying weakness in the value proposition, but rather that different approaches are needed to serve this highly untapped market space. Increasingly, investors are recognizing this need, and entering the C&I market with the intent to reduce transaction costs, standardize the due diligence and underwriting process, and bundle projects to achieve the scale necessary to access more efficient capital markets. There are excellent prospects of higher risk-adjusted returns and comparatively less competition for those successful in mitigating the risks inherent to the C&I market. Lucrative opportunities increasingly concentrated in states with healthy SREC markets As solar deployment has accelerated and installation costs continue their downward trend, it would be reasonable to conclude that there should be no shortage of lucrative solar project investment opportunities. But then, you would be overlooking the countervailing impact of progressively lower and shorter term PPAs, particularly in markets dominated by a small number of incumbent utilities with concentrated negotiating power to determine the terms. PPA rates are now consistently falling below the $60/MWh threshold, sometimes with no escalators, and for periods as short as 10 years. Returns to solar project investors are being squeezed to the point where traditional investors in the space may be starting to look elsewhere to meet their hurdle rates. Solar project investment activity is increasingly focusing on the handful of states with healthy SREC markets. Massachusetts and New Jersey are the most prominent in the mix. Massachusetts SREC I bid prices are trading above $450/MWh and SREC II bid prices are around $270/MWh, though these markets are on hold due to pending legislation. New Jersey SREC bid prices are all hovering around $280/MWh. Washington D.C. and Maryland both have SREC programs with bid prices above $100/MWh, which rounds out the most impactful programs from a price standpoint. These additional revenue streams can help to offset the lower PPA rates, and increase risk-adjusted returns to a level that is attractive to many investors. You may ask - what is driving these SREC bid prices? To which I would respond - the oldest economic story in the book is playing out in these markets The supply of solar (solar project installations) and the demand for solar (driven largely by RPS and solar carve-out policies) govern SREC prices. The extension of the solar ITC is projected to increase the solar pipeline over the next five years, thereby increasing the supply. On the other hand, there is concern about dwindling demand for SRECs, as program caps and other RPS targets are met. Already in Massachusetts, we are seeing developers faced with increased risks due to caps being hit for the SREC II program. When you combine the increasing supply with decreasing demand, you quickly get the picture that SREC prices may not be able to exist at their current levels for many years to come. This eventuality has motivated solar developers and investors to quickly take advantage of the current market conditions in these target markets. The latest U.S. Solar Market Insight Report from GTM Research and the Solar Energy Industries Association reveals that the U.S. installed a record 7.3 GW of PV capacity in 2015, with solar installations surpassing natural gas capacity additions. Overall, solar accounted for 29.5% of all new energy capacity additions in the U.S. in 2015. U.S. Solar PV Installations, 2000-2015 (Source: GTM Research / SEIA U.S. Solar Market Insight Report) Among the different solar sectors in the U.S., residential PV has been the fastest-growing market segment, expanding by at least 50% over the past three years and 66% in 2015. By Q1 2016, the number of U.S. homeowners with rooftop solar is expected to cross the 1 million mark. Indeed, the falling costs of installation paired with rising retail electricity rates make residential solar economics increasingly attractive in a growing number of states. A GTM study released in February found that 20 U.S. states have reached grid parity for residential solar. However, the increase in rooftop solar installations and the accompanying rise of net energy metering policies have revealed several issues underlying high penetrations of solar, among them:
In response to these concerns, and especially the concern among utilities that a decline in sales will generate insufficient revenue to cover the fixed costs of maintaining the grid, some utilities have suggested imposing higher fixed charges on their customers as a method to recoup costs. In 2015 alone, 61 utilities in 30 states requested public utility commissions to increase fixed charges, making it the most frequent policy proposal impacting distributed solar in the last year. 21 utilities in 13 states proposed adding new or increasing existing charges specific to residential solar customers, with the median requested increase at $5 per month. While seemingly a “quick fix” for utilities’ declining revenue concerns, fixed charges do not vary with usage and cannot be avoided with energy net metering credits. Thus, higher fixed charges significantly reduce the financial value of installing solar PV systems. Moreover, fixed charges harm low income and low usage customers and they fail to provide accurate price signals to customers, thereby reducing customer incentives to save on energy use. Research institutes, think tanks, and regulatory agencies have suggested other approaches to address concerns associated with net energy metering in high solar penetration states, among them: time-of-use pricing, smart metering, locational marginal pricing, minimum bills, and revenue decoupling. These suggestions are currently being weighed by legislators and public utility commissions in at least 27 states. Unfortunately, rate review processes are lengthy, and in the meantime the solar industry is paying the price for policy uncertainty. After the Nevada Public Utility Commission’s controversial December 2015 decision to slash net energy metering, many residential solar installation companies halted operations in Nevada, with giants like SolarCity and Sunrun exiting the state. This month, Massachusetts reached its net metering and REC caps, halting operations of solar developers and installers in a state that has more solar jobs than any other state except California. Recent Action on Net Metering, Rate Design, and Solar Ownership Policies (Source: N.C. Clean Energy Technology Center, 50 States of Solar: A Quarterly Look at America’s Fast-Evolving Distributed Solar Policy Conversation.) One state that has remained below the solar radar is suggesting a new approach for addressing solar rate design concerns. Maine’s new proposal for replacing net energy metering with a market aggregator is making ripples in the solar policy world for its innovative ratepayer-focused approach. The proposal contemplates the creation of a market aggregator that would purchase energy, RECs, capacity value, and ancillary services potential from distributed energy generators at a fixed per-kWh rate guaranteed under a 20-year contract. Centralizing procurement is supposed to reduce transaction costs and create new opportunities for the aggregator to sell the different attributes solar energy provides in applicable markets. Based on a Maine Public Utility Commission March 2015 study that estimated the value of distributed solar at $0.337/kWh, the proposal suggests a starting purchase price from distributed energy generators of $0.20/kWh, higher than the current net energy metering rate ($0.13/kWh) but lower than the $0.337/kWh Maine value of solar estimate. The Public Utility Commission can set a different rate (higher/ lower) based on market conditions and other criteria (there is a lower rate for small commercial projects of 1 to 5 MW). For the wholesale distributed generation market, the aggregator will conduct a quarterly reverse auction for specified levels of installed capacity, with the lowest offer winning a purchase contract from the aggregator who then sells the energy and attributes in the applicable markets. The program is hailed by solar advocates, utilities, and regulators as meeting the needs of all stakeholders involved. Solar customers enjoy rate certainty for a period of twenty years, which is the common term for solar equipment financing. At the same time, all ratepayers are set to enjoy the revenues from the sale of the aggregated energy and attributes in wholesale markets, which are to be allocated equally across the entire rate base. Overview of Market Transactions (Source: Strategen, A Ratepayer Focused Strategy for Distributed Solar in Maine.)
The bill incorporating the new solar program was endorsed by a bipartisan group of lawmakers, environmental organizations, utilities, solar installers, and consumer advocates. According to the bill’s sponsors, the new program will not only boost Maine’s solar industry but also save $100 million for ratepayers. For those who thought that community solar marks the second revolution in the solar market, Maine’s promising new solar purchase program serves as another example of how aggregation of solar generation and attributes could increase returns for all parties involved. The emerging lesson from these two examples is that with solar energy, economies of scale could be achieved without unnecessary investments in large and expensive infrastructure. Innovative market models and creative policy approaches will determine the next leaders of the solar world. Monthly and Annual Range of Wholesale Electricity Prices (Source: EIA)
Related data points:
PPAs are getting structured with shorter terms, which actually may end up being a boon for solar project investors Contracted revenue provides the basis of solar project financing. When long-term power purchase agreements (PPAs) came into use for solar projects, they created stable cash flows that risk averse investors could trust. The simplest solar projects being built today still rely on PPAs that typically range from 15 to 20 years. This PPA model is being adapted to current market conditions, with some potentially unintended consequences. Recently, evidence is mounting in regulated markets that utilities are signing PPAs for shorter durations. For example, Duke Energy, serving more customers than any utility in the U.S., is now consistently on record as offering progressively lower PPA rates over shorter timeframes. For a solar project developer, this can be seen as problematic, as you now have a shorter period of secure cash flows generated by your project, which could undermine the basis for a project’s valuation. But this all hinges on what you believe about the future of wholesale electricity prices. Once the term of a PPA is complete for generators that are “in front of the meter,” an option is often available to then switch to selling the electricity generated on the wholesale markets. Given the downward trends in PPA rates, which are now consistently falling below the $60/MWh threshold, the wholesale market may end up yielding higher returns if wholesale rates increase according to industry projections. Thus, a solar project with a shorter PPA may end up yielding higher returns than one with a longer PPA, albeit with some additional merchant risk associated with participating in wholesale markets. Quantifying merchant risk can be a complex task, and is not to be disregarded, but neither does it need to render a project financially infeasible. Are utilities preparing for a future with higher natural gas prices? From the perspective of the utility negotiating the PPA, there are some interesting implications for why a utility like Duke Energy would want to short-term negotiate PPAs. Fundamentally, they must believe that electricity generation will not get substantially more expensive in the future. This is likely a product of the mantra that natural gas prices will remain low for the foreseeable future, an assertion that does not seem to be supported by an objective forecast of the price of natural gas. If natural gas prices rebound in the future, as they inevitably will at some point, wouldn’t it be prudent to have a portfolio of long-term solar PPAs to keep electricity retail rates from spiking? This possibility seems largely absent from the current thinking around PPAs, even as electricity generation from solar has become cheaper than natural gas. n addition, there must be the belief that solar PPAs and other equivalent electricity sources will become progressively cheaper in the future. If trends from the past decade are any indication, this is a safe bet. Yes, solar costs are projected to continue rampant decreases in costs over both the near- and long-term future. So, the solar PPA that Duke signs in 2018 will likely be at a lower rate than the one signed in 2016. But, if natural gas prices do not support continued expansion of natural gas power plants, can solar project pipelines be able to make up the difference? Perhaps, but it is no sure bet. Thus, the question is one of scale and hedge risk against a future in which today’s anomalously low natural gas prices do not continue in perpetuity. Evolution of solar project investing is driving out investors seeking high yield As solar project finance emerged from its inception as a niche market to a broadly appealing investment class, the search for risk-adjusted returns has naturally become more of a challenge. Early investors in solar project finance were attracted by the double-digit return potential based on long-term contracted cash flows. As the perception of high technology risk receded into the past, the overall risk profile of solar projects started to look more like bonds and other fixed income assets. Stable and predictable cash flows backed by a tangible asset coupled with very low long-term operating costs and free fuel made for an enticing proposition. Looking over a cash flow statement, solar projects started to look like many other revenue generating infrastructure assets - bridges, toll booths, pipelines, etc. Large infrastructure funds and other investors familiar with these types of revenue generating assets entered the market and started to compete with the incumbents, specialty investment funds. But now we are seeing a new type of entrant into the market. Now, the cat is out of the bag, so to speak. Solar project investing is no longer a niche activity, and there is a swell of interest in acquiring solar projects for their predictable cash flows. But as the solar industry has matured, there is less value being left on the table. Or rather, solar investors are no longer able to easily generate unlevered returns in the double digits, at least not without the help of incentive programs such as SRECs to generate revenue outside of the PPA structure. Whereas private equity and investment funds with higher costs of capital have been big players in financing solar projects to date, we may be seeing a shift to banks, insurance companies, and institutional investors with large appetites for low risk, and more modest returns over long time horizons. As large solar portfolios start to enter the market seeking investors, increasingly they may be turning to the funds with the greatest tolerance for lower returns. Their success in this market will depend upon how quickly that can become savvy on the intricacies of solar project finance. Further reading:
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