AHEAD OF THE PACK Solar, the new Gateway to the decentralised Energy System. May / SolarPower Europe / AHEAD OF THE PACK

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AHEAD OF THE PACK Solar, the new Gateway to the decentralised Energy System May 2016 1 / SolarPower Europe / AHEAD OF THE PACK

ABSTRACT New dynamics are taking place in the European power sector. The strong cost decrease of distributed generation and storage technologies makes our energy system more decentralized but also, and more importantly, transforms the way value is created. Clearly, players in the retail market today need to operate closer to the end-consumer. Against this background and in order to shed some new light on the current debate around prosumers, this report analyses different policy scenarios. It models - for three representative European markets several combinations of solar and storage solutions. Each time, various options are considered depending on how the self-consumed and injected solar electricity is remunerated. This approach allows to better estimate the concrete economic benefits for end-consumers and, from there, to explore how energy suppliers incumbent or new entrants will be able to capture business opportunities by creating new value propositions for their customers. These new offers will in turn make distributed generation smarter and more system relevant. In this new decentralised world, solar will become a new factor of performance and differentiation amongst energy suppliers. Some may decide to continue operating in a business as usual mode. Others will seize this new opportunity, create new business models, and run ahead of the pack. SolarPower Europe / AHEAD OF THE PACK/ 2

Table of Contents ABSTRACT 2 CHAPTER 1. DECENTRALISATION: A NEW MEGA-TREND IN THE EUROPEAN POWER SECTOR 5 CHAPTER 2. CONSUMER BENEFITS KEY FINDINGS 7 CHAPTER 3. THE PROSUMER: A DRIVER FOR INNOVATIVE BUSINESS MODELS 10 CHAPTER 4. NEW BUSINESS MODELS, NEW BENEFITS FOR THE ENERGY SYSTEM 14 CHAPTER 5. CONCLUSIONS AND RECOMMENDATIONS 16 APPENDIX - OVERVIEW OF MOST IMPORTANT INPUT PARAMETERS USED 18 Acknowledgments: Hochschule für Technik und Wirtschaft (HTW) Berlin Research: Thomas Döring, SolarPower Europe Co-authors: Thomas Döring and Alexandre Roesch, SolarPower Europe SolarPower Europe / AHEAD OF THE PACK/ 3

EXECUTIVE SUMMARY The analysis conducted in this report shows that solar alone or in combination with battery storage - can bring economic benefits to a growing share of European consumers. However, with potentially changing policy designs and an increasing share of prosumers, there is a need to develop new business models to ensure that self-generation and consumption are made smarter and benefit the whole energy system. At a time when maintaining or gaining consumer satisfaction is more challenging, offering new decentralised energy solutions becomes a factor of performance and differentiation amongst electricity suppliers. Only innovative players will be able to maintain the needed trust and thereby grow their business in this smart environment. These new strategies will bring system benefits. New business models will not only make distributed generation more accessible but they will also unlock flexibility potential at consumer level by offering services to grid operators. This overall transition requires a dynamic and adequate regulatory environment. The following regulatory adjustments both at European and national levels are needed to develop a prosumerfriendly policy: Develop a dedicated policy framework for prosumers of renewable energy within the revised Renewable Energy Directive. Clarifying the definition and rights of prosumers, simplifying administrative procedures with one-stop-shops and encouraging the emergence of new financing models (e.g. third party financing, cooperatives, pooling of assets) should make self-generation easy to access. Prosumers should be encouraged and not hindered, as they directly finance the energy transition and the achievement of our 2020 and 2030 renewable energy targets. Adapt market rules to accelerate the development of enablers and make selfgeneration and consumption smarter. The upcoming market design reform should further facilitate demand response and provide an EU-wide legal definition of storage. As shown by our economic analysis (and in various real-life examples in a number of European countries), applying taxes and grid charges to self-consumed electricity in an abrupt manner has a dis-incentivising effect on the progressive smartening of decentralised generation. Prosumers should not be exposed to any tax on the electricity they self-generate and consume. Make distribution grid tariffs fit for the energy transition. A prosumer-friendly approach should be reflected in the way distribution tariffs are set by national regulators. Particular attention should be given to the quantified and real impact of prosumers on the grid at the time when tariffs are set (every 4 to 5 years on average in Europe). Guidelines on how to set these tariffs could be developed at European level. Ensure a proper remuneration of services provided by distributed generation as this will facilitate its integration in the system. Business models will develop on the basis of combined offers able to bundle several revenue streams. The ancillary services market should therefore be further developed especially at distribution level. In parallel, market design rules should be adapted to ensure that the excess of (aggregated) solar electricity will be properly remunerated by the market. Moreover, ENTSO-E network codes (and their implementation at national level) should ensure the proper participation of aggregated solar PV in all markets. Reflect upon a combination of the market integration and constraint scenarios, as a suitable variant in a transition towards a complete integration of prosumers. Frameworks at national level should strive a balance between maintaining a minimum level of remuneration for the electricity injected into the grid and exposing the self-consumed electricity in a staggered approach to grid charges in a way which reflects the technology cost digression of solar and storage. The report and all figures can be downloaded on www.solarpowereurope.org SolarPower Europe / AHEAD OF THE PACK/ 4

1 CHAPTER 1. DECENTRALISATION: A new mega-trend in the European power sector For an increasing number of consumers in Europe, distributed generation combined with other smart solutions represents the perfect way to control their energy bill. Other behavioral factors may of course play a role in individual decisions, but in essence, economic benefits probably remain the key consideration of people who invest in on-site generation. Indeed, the fact that solar generation costs are today low and expected to decline 1 further is perceived as a strong hedging strategy in a context of increasing electricity prices. The economic benefits for these new types of consumers (prosumers), however, depend on the policy arrangements at the retail level. In particular, the regulatory treatment of selfconsumption i.e. the fact that on-site power generation is used below a given connection point either instantaneously or in a deferred manner via storage and the remuneration of the excess of electricity injected into the grid will to a large extent determine the financial benefits for consumers. In order to shed some new light on this debate, SolarPower Europe has developed three policy scenarios for residential consumers in Germany, the UK and Portugal 2 : A reference scenario which assesses the economic benefits for consumers under the current market conditions. In this case, we considered the regulatory arrangements in place in these three countries in June 2015. Self-consumed electricity is usually valorized at the full retail price while the excess of electricity is generally remunerated above wholesale price levels. A market integration scenario, in which the excess of distributed generation (i.e. not self-consumed but injected into the grid) would not benefit from any form of financial support and would be remunerated at average wholesale price levels. This is to reflect a situation where the level of support schemes for solar would be progressively phasedout. In this scenario, the self-consumed electricity is remunerated in the same way as in the reference scenario. 1 Solar PV generation costs are expected to decrease by 30-50% from 2014 to 2030, depending on the volume growth and learning rate. This development does not assume any major technology breakthroughs but is a natural cause of continued efforts in reducing materials use, improving efficiency and developing manufacturing processes and as well as further reduction of operating costs. European PV Technology Platform, 2015. 2 These three markets were selected on the basis of three criteria: i) their variety in solar irradiation, ii) their variety in support schemes and iii) a level of electricity prices in 2014 for households and commercial consumers above 0.2 /kwh and 0.1 /kwh respectively. The latter specifications were chosen given their relative cost-reflectiveness, having in mind that retail electricity prices remain today regulated in several other EU countries. SolarPower Europe / AHEAD OF THE PACK/ 5

A constraint scenario, in which the self-consumed electricity would not be valorized at the full retail electricity price. This is to reflect a situation where the self-consumed electricity would be exposed either to grid charges or taxes, or both. The excess electricity in this scenario is remunerated in the same way as in the reference scenario. Figure 1 below provides an overview of the three scenarios. For each of them, an analysis was conducted in order to assess whether combining solar with decentralised (battery) storage would make economic sense considering two different battery sizes 3. FIGURE 1 OVERVIEW OF ASSESSED POLICY SCENARIOS SOLARPOWER EUROPE 2015 Note: the constraint scenario anticipates two potential developments. The first one relates to the fact that the prosumer s decreasing electricity grid demand (and therewith costs) due to selfconsumption will ultimately lead to a lower financial compensation for grid services, which are currently remunerated via the electricity price on a volumetric basis. In such a case, it can be argued that a shift toward capacity-based distribution grid tariffs would be needed to secure the remuneration of grid costs. Secondly, the constraint scenario takes into account that an increasing solar PV penetration may not necessarily reduce peaks of injection or consumption. These peaks can be reduced by using battery storage, or distributed generation can be used to provide services to the grid operators. This is why the savings potential linked to selfconsumption in this scenario is higher when using storage. 3 Batteries of 2,3 and 8,3 kwh usable capacity have been considered in order to assess two different trends with self-consumption ratios of around 50 and 70% respectively in the residential segment. Battery sizes and corresponding self-consumption ratios were derived based on an external online simulation tool published by the Hochschule für Technik und Wirtschaft (HTW) Berlin, http://pvspeicher.htwberlin.de/unabhaengigkeitsrechner/# SolarPower Europe / AHEAD OF THE PACK/ 6

2 CHAPTER 2. CONSUMER BENEFITS KEY FINDINGS In order to present the impact of the different scenarios on the economic benefits of endconsumers in a consolidated manner, the Figure 2 below shows the Internal Rates of Return (IRR) achieved in each scenario in each country. This basically gives an indication to the consumer on the return they can expect in relation to the initial investment made. FIGURE 2 INTERNAL RATES OF RETURN FOR CONSUMERS IN THE DIFFERENT POLICY SCENARIOS SOLARPOWER EUROPE 2015 SolarPower Europe / AHEAD OF THE PACK/ 7

The following conclusions can be derived from this analysis: Generally speaking, combining solar with storage in the reference scenario proves economically feasible today. However, and very importantly, solar alone remains a better deal in such a scenario. It indeed achieves either better or very similar economic results than solar combined with small batteries, while solar combined with large batteries likely remains the least beneficial variant with regard to medium timeframes (five years and more). This is because the additional investment costs associated with larger batteries reduce the monetary benefits to an extent which cannot be compensated by higher self-sufficiency rates. In the case of Germany, our sensitivity analysis shows that a tipping point may be reached when cost of batteries will be reduced by 30% and 70% for small-size and large-scale batteries respectively. In the UK, on the contrary and based on the regulatory framework in place in June 2015, there was no strong business case for storage. In Portugal, the reference scenario can be considered as a market integration scenario, since according to the schemes in place in June 2015 the excess of electricity is already valorized only at the average wholesale price and does not benefit from any feed-in tariff. In the market integration scenario (remunerating excess electricity only at the level of average wholesale prices), in the three countries considered solar combined with small batteries already brings slightly higher returns for the consumers than solar without storage. This suggests that such a scenario would incentivise prosumers to couple their solar system with storage in order to maximise their selfconsumption rates, hence creating new opportunities for the further smartening of decentralised solar generation. This only remains valid if the self-consumed electricity can be valorised at the full retail electricity price. In the constraint scenario (exposing self-consumption to grid charges and taxes), our analysis shows that the total benefits for consumers are much reduced in Portugal. This is also the case in Germany for systems combined with batteries. Our sensitivity analysis shows that even a slight reduction of the remuneration of the excess of electricity in that country will make the constraint scenario less favourable than the other scenarios. In the UK, the constraint scenario has a lower impact given the schemes that were in place in 2015. Also, storage (whatever the size) does not help counterbalance this trend. Generally speaking, the constraint scenario has a dis-incentivising effect on the progressive smartening of decentralised solar generation. SolarPower Europe / AHEAD OF THE PACK/ 8

A DEEPER LOOK AT THE GERMAN EXAMPLE This heat-map provides an easy to grasp comparison of all scenarios and different Solar & Storage combinations in Germany. The worst economic results are shown in the upper left (red) area indicating unfavourable economic results, i.e. high dynamic payback times, low net present values and low internal rates of return. Correspondingly, the best achievable economic results are presented in the lower right (green) area. This analysis confirms that in the medium term consumers will engage more in on-site generation as they will be able to derive economic benefits from it. This raises the question of the new business models which will emerge in parallel to this evolution. SolarPower Europe / AHEAD OF THE PACK/ 9

3 CHAPTER 3. THE PROSUMER: A driver for innovative business models The shift towards a system where the generation assets are located close to and/or owned by the end-consumers may represent a disruptive change for energy suppliers. However, it also creates new opportunities. Prosumers have new, different needs which therefore require new, different offers. In the fast-changing power sector, energy suppliers face increasing challenges in order to maintain or improve trust with their customers. A study conducted by Opower 4, a US-based software service provider to utilities, shows for instance that there is a significant gap between customer expectations and electricity supplier service-performance. FIGURE 3 CUSTOMER EXPEXTATIONS AND ENERGY SUPPLIERS PERFORMANCE GAP RELATED TO COSTS 37% 51% 48% USA Source: Opower, 2013 OTHER ENGLISH SPEAKING COUNTRIES (UK, AUSTRALIA, NEW ZEALAND, CANADA) EU Performance gap Satisfaction SOLARPOWER EUROPE 2015 4 Five Universal Truths about Energy Consumers. SolarPower Europe / AHEAD OF THE PACK/ 10

Paradoxically, consumers who face higher retail prices are not necessarily less satisfied with the cost-performance of their supplier when compared to consumers in countries with lower prices (Opower, 2013). This suggests that consumers may not only evaluate their suppliers on the actual cost per kwh but also on additional elements such as services, billing information, support, etc. Almost 60 % of consumers globally especially those between 18 and 34 years show for instance interest in investments that increase their self-sufficiency (Accenture, 2015). Against this background, a recent survey conducted by Accenture shows that energy suppliers are rather well-positioned to handle that situation. 55% of customers are for instance interested in purchasing or signing up for solar PV products within a period of 5 years (and this trend has increased over the last two years) and ranked energy suppliers within their preferred providers for such products (Table 1). TABLE 1 OVERVIEW OF CONSUMERS PREFERRED SOLAR PV PRODUCT PROVIDERS Specialized Solar PV company 74% Electricity supplier 71% Home improvement / Electronics provider 41% Cooperative / Community organization 38% Maintenance / Repair company 33% Phone / Cable Provider 18% Online retailer 16% Source: Accenture, 2015 Considering the variety of regulatory environments across Europe and the declining wholesale electricity prices, a larger share of the value for energy stakeholders is now created close to the end-consumers, precisely where utilities are missing out significant opportunities. Hence, there is a wide untapped potential to develop new business models around decentralised on-site generation. Figure 5 below illustrates where electricity suppliers may in that context have strong capabilities to develop a new Decentralised PV value proposition. SolarPower Europe / AHEAD OF THE PACK/ 11

FIGURE 4 DECENTRALISED PV VALUE PROPOSITION AND ELECTRICITY SUPPLIERS CAPABILITIES (Subjective assessment based on W Stenhagen & Wuebker, 2011) Legend: Electricity supplier capabilities SOLARPOWER EUROPE 2015 Given some of the gaps identified above and having in mind some regulatory aspects (e.g. the need to ensure a separate and safe data-management), future business models are likely to be based on new partnerships among electricity suppliers, specialised companies in the solar sector as well as IT providers (e.g. home automation etc.). As shown in Figure 5 below, such partnerships represent an effective way of creating higher values for both suppliers and consumers. FIGURE 5 OPTIONS TO INCREASE THE BUSINESS MODEL VALUE OF DECENTRALIZED SOLAR PV Source: Bell, Creyts, Lacy, & Sherwood, 2014 SOLARPOWER EUROPE 2015 SolarPower Europe / AHEAD OF THE PACK/ 12

Overall, the role of electricity providers in the future will be related to three main dimensions (Figure 6): Ensuring access to decentralized solar PV by using their existing negotiating power to offer better deals to their customers. This role could be extended by offering additional options such as access to community solar programs and platforms similar to peer-topeer communities. Providing a reliable combination of solar PV with digital and automation technologies by offering product packages, which support consumers to really benefit from smart technologies (home appliances, smart metering, etc.). Leveraging prosumer flexibility to support the grid operation by operating decentralized PV capacity, advanced storage and inverter technologies to provide remunerated grid support services and valorize the consumers demand response potential created by this enhanced flexibility. FIGURE 6 THE ROLE OF ELECTRICITY SUPPLIERS AROUND DECENTRALISED SOLAR PV Reliable combination & added value of solar PV with digital and automation technologies Utilization of capacity for grid support Decentralised Solar PV Ensuring availability and access to decentralized solar PV Source: Bell, Creyts, Lacy, & Sherwood, 2014 SOLARPOWER EUROPE 2015 SolarPower Europe / AHEAD OF THE PACK/ 13

4 CHAPTER 4. NEW BUSINESS MODELS, NEW BENEFITS FOR THE ENERGY SYSTEM The fact that consumers can derive real economic benefits from distributed generation will trigger new value propositions. As seen above, these new offers are also likely to incorporate system services. Today, as the second most deployed smart technology in the energy system (after smart meters), solar can provide system services such as voltage support (reactive power) and negative balancing power, i.e. ramp down. When combined with batteries, solar is also capable of providing positive balancing power (i.e. ramp up), can support black starts 5 and can limit the injection peak during mid-day (thereby reducing grid impact). The REserviceS project 6 conducted an in-depth analysis of the technical and economic feasibility of providing system services with wind and solar technologies. Figure 8 below summarizes the outcomes of the project. It shows that solar PV, in an aggregated format, can already provide a large number of system services from a pure technical/economic perspective. It also shows that procedural prerequisites at national level to fully exploit this potential are not in place yet. 5 In case of total power outages certain power stations must be able to start up without being able to draw power from the grid. This is called the black start service (Elia, 2015) 6 http://www.reservices-project.eu/ SolarPower Europe / AHEAD OF THE PACK/ 14

FIGURE 7 OVERVIEW OF POTENTIAL SYSTEM SERVICES PROVIDED BY SOLAR PV 78 Technical Aspects Implemented Partially implemented / implementable / low cost investment to enable required capacities Not implemented / implementable / high cost to implement Existing Grid Support Services Procedures: Grid Code Requirements, prequalification procedures and Network Code Requirements, amongst others Well defined requirements / specifications in most procedures at European level Poorly defined requirements / specifications or not addressed in most procedures Not defined / not possible due to requirements in all or most procedures New Grid Support Services SOLARPOWER EUROPE 2015 This shows that in a decentralized energy world, system services can and will have to come more from the flexibility created at the consumer level by distributed generation, storage and demand response. More importantly, these distributed flexibility assets will be able to provide better services if they are aggregated. The increased competition at retail level and the new partnerships described above will create new opportunities to better harvest this untapped potential. The appearance of new commercial offers whereby consumers are offered a capped electricity bill or the pooling of distributed storage capabilities are just some initial signals that business models are evolving in order to provide both economic benefits to consumers and services to the grid operators. 7 Source: Van Hulle, et al., 2014 8 FCR: Frequency Containment Reserve, FRR: Frequency Restoration Reserve, RR: Replacement Reserve FFR: Fast Frequency Response, RM: Ramping Margin, SSVC: Steady State Voltage Control, FRCI: Fast Reactive Current Injection SolarPower Europe / AHEAD OF THE PACK/ 15

5 CHAPTER 5. CONCLUSIONS AND RECOMMENDATIONS The analysis conducted in this report shows that solar alone or in combination with storage - can bring real economic benefits to a growing share of European consumers. With prosumers comes the need to develop new business models to ensure that self-generation and consumption is made smarter and benefits the whole system. At a time when maintaining or gaining consumer satisfaction is more challenging than ever, offering new decentralized energy solutions to prosumers becomes a factor of performance and differentiation amongst energy suppliers. Only innovative players will be able to create the needed trust and thereby grow their business in this smart energy environment. These new strategies will in turn bring system benefits. New business models will not only make distributed generation more accessible but they will also unlock the flexibility potential at consumer level by offering services to grid operators. This overall transition requires a dynamic and adequate regulatory environment. The following regulatory adjustments at both European and national levels - are needed to develop a prosumer-friendly policy: 1. Develop a dedicated policy framework for prosumers of renewable energy within the revised Renewable Energy Directive. Clarifying the definition and rights of prosumers, simplifying administrative procedures with one-stop-shops and encouraging the emergence of new financing models (e.g. third party financing, cooperatives, pooling of assets) should make self-generation easy to access. Prosumers should be encouraged and not hindered, as they directly finance the energy transition and the achievement of our 2020 and 2030 renewable energy targets. 2. Adapt market rules to accelerate the development of enablers and make selfgeneration and consumption smarter. The upcoming market design reform should further facilitate demand response and provide an EU-wide legal definition of storage. As shown by our economic analysis (and in various real-life examples in a number of European countries), an abrupt implementation of the constraint scenario, where taxes or grid charges are applied to self-consumed electricity, has a dis-incentivising effect on the progressive smartening of decentralised generation. Prosumers should therefore not be exposed to any tax on the electricity they self-generate and consume. 3. Make distribution grid tariffs fit for the energy transition. A prosumer-friendly approach should be reflected in the way distribution tariffs are set by national regulators. Particular attention should be given to the quantified and real impact of prosumers on the grid at the time when tariffs are set (every 4 to 5 years on average in Europe). Guidelines on how to set these tariffs could be developed at European level. SolarPower Europe / AHEAD OF THE PACK/ 16

4. Ensure a proper remuneration of services provided by distributed generation as this will facilitate its integration in the system. Business models will develop on the basis of combined offers able to bundle several revenue streams. The ancillary services market should therefore be further developed especially at distribution level. In parallel, market design rules should be adapted to ensure that the excess of (aggregated) solar electricity will be able to be properly remunerated by the market. Moreover, ENTSO-E network codes (and their implementation at national level) should ensure the proper participation of aggregated solar PV in all markets. 5. Reflect upon a combination of the market integration and constraint scenario, as a suitable variant in a transition towards a complete integration of prosumers. Frameworks at national level should strive a balance between maintaining a minimum level of remuneration for the electricity injected into the grid and exposing the self-consumed electricity in a staggered approach to grid charges in a way which reflects the technology cost digression of solar and storage. SolarPower Europe / AHEAD OF THE PACK/ 17

APPENDIX - Overview of most important input parameters used

SolarPower Europe / AHEAD OF THE PACK/ 19