Scientific report for the 1. – 4. Period PART 1 – INFORMATION ON PROGRAM 1.1. Title of the programme: Energy efficient and low-carbon solutions for a secure, sustainable and climate variability reducing energy supply 1.2. Programme acronym (LATENERGI) 1.3. Programme web page address: http://latenergi.rtu.lv 1.4. Programme principal investigator (PI): Leonīds Ribickis, +371 67089300, [email protected] (name, surname, phone, e-mail) 1.5. Contact person Oskars Krievs, +371 67089900, [email protected] (name, surname, phone, e-mail) 1.6. Report for a period from August 1, 2014 till June 30, 2018. 1.7. The aim of the programme and objectives The aim of the program is to carry out research on technologically innovative and cost efficient solutions for sustainable energy production and consumption, for boosting energy efficiency and for the development of environmentally friendly renewable energy resources. In the programme implementation period, the targets of the programme have been achieved by carrying out a number of activities and fulfilling multiple tasks:  Various technological solutions have been elaborated for deploying DC micro- grids in industrial or household objects: power converters for integration of energy storage and PV panels into DC micro-grid, interfacing the DC micro-grid to AC distribution grid, as well as a DC grid emergency tripping device;  A prototype of multi-channel measurement system for detailed monitoring of electrical energy flow has been developed and approbated in two industrial sites;  Technological solutions and power converter prototypes have been developed for reactive power control in order to increase energy efficiency of industrial objects, for charging and managing electrical vehicle batteries, for increasing energy efficiency of electrical drive systems with braking energy recuperation, as well as for harvesting wind energy;  Long-term, medium-term and short-term forecasting methods, algorithms and software of processes influencing power system operation has been developed; P-1  Used for power system balancing a probabilistic assessment methodology and tool of the economic potential from electricity end-user participation in explicit demand response (DR) is developed;  New design of synchronous reluctance motor with lowered electromagnetic torque pulsations was developed;  Based on the study performed: “Electricity Price and the Factors Impacting It”, decree No. 530 of the Cabinet of Ministers of the Republic of Latvia has been adopted in Riga, on September 22, 2017 (MOM No. 42, Article 56);  The development of technologically innovative, efficient, cost-effective solutions for sustainable energy production and consumption, and for energy efficiency improvement;  Ensuring in-depth research on environmentally friendly renewable energies, which provides an opportunity to increase the share of renewable energy in energy use;  The system dynamics model of the energy sector was created;  The development strategy of a sustainable transport sector in Latvia was elaborated, proposals for implementation of the Energy Efficiency Law for increasing the energy efficiency of buildings were presented;  Research was carried out on the gradual introduction of the 4th generation heat supply system in Latvia, the development of low-carbon solutions and innovative climate technology, the concept of climate adaptation was developed and the resilience of the energy sector of the city was evaluated;  The tendencies of development of energy planning of local governments of Latvia are evaluated;  An analysis of the technological solutions of the optimization of the industrial sector and production companies and the improvement of the energy efficiency of the Latvian industry;  Eco-design concept and analysis of industrial symbiosis were developed;  New technology to efficiently convert lignocellulosic biomass to liquid biofuel (bioethanol, biobutanol);  Process optimization to ensure efficient and simple conversion process, eg., biomass size evaluation, impact of resource types, membrane technology processes, fermentation);  New chemical and thermochemical technologies for biofuel (biodiesel and bio-oil) production have been developed;  Overview and performance analysis of biogas yield potential of different biomass clarification have been estimated and anaerobic fermentation process optimization has been studied;  New technologies for using hydrogen in the energy sector have been developed;  Research on efficient conversion of lignocellulosic biomass into biofuel (bioethanol, biobutanol) has been performed;  It is created the new version of the Latvia energy-environment optimisation model MARKAL-Latvia which comprises a number of new developments;  In the new version of energy-environmental model MARKAL-Latvia it is put into practice the elastic demand modelling methodology, namely, the demand for energy service reacts on energy price change in the particular sub-sector; P-2  The instruments for GHG emissions reduction measures’ implementation in energy sector are analysed and assessed identifying the main problem issues restricting application of different instruments;  The measures that are applicable and can be implemented in Latvia for emissions reduction in the energy sector are described with algorithms in the MARKAL- Latvia model. The measures are described pointing out their potential in emissions reduction, the total costs for the measures implementation, including investments, operational costs, etc.;  The methodology for the evaluation of Latvia energy supply security has been developed based on supply security indicators system. The numerical values of selected indicators are calculated and compared in the base year and in modelled scenarios;  By applying MARKAL-Latvia model, the ex-post assessment, for the years 2000- 2015, of the energy policy impact upon Latvian energy system characterising indicators and GHG emissions amount in energy sector is done;  Modelling and analysis of Latvia energy system alternative development scenarios, including the energy and climate policy targets in the scenarios’ definition, are performed. As the results of modelling, the GHG emissions amount, specific costs of GHG emissions reduction in energy sector, energy saved due to implementation of energy efficiency measures, fuel structure and other indicators characterising energy sector are evaluated;  Innovative technologies for heating and cooling with solar energy use have been developed;  Renewable energy potential evaluation and RES for electricity production by 2025 have been evaluated;  New technologies for biomass use were investigated: long-term biomass energy potential and analysis of the optimal biomass resources used for energy production have been estimated; different types of biomass emissions assessment in the various biomass utilization processes for energy production have been researched; the emission characteristics of fuel materials (RDF and SRF) from waste and their comparison with wood chips in Latvian boiler houses was determinate;  Improved PV solar cell production methodology;  The analysis of the operation efficiency of wind power plants in Latvia has been carried out;  The improvements have been introduced in the methodology for switched reluctance machine;  Overview and performance analysis of Latvian biogas plant, biogas yield potential of different biomass clarification have been estimated and anaerobic fermentation process optimization have been studed;  Events for public information on innovative technologies in the energy sector, have been organized, raising the awareness about the sustainable development of the energy sector in Latvia; In general the objectives of the programme have been achieved. The performance indicators set for the programme have been overachieved in the majority of the positions, which shows the actuality of the topics researched within the programme. The growing interest from various government organizations (including Ministry of P-3 Environmental Protection and Regional Development and Ministry of Economics) in the results achieved within the research program should be highlighted as well. 1.8. Executive summary of the programme (max. two A4 pages. Summary of scientific results achieved during reporting period, their scientific and applicational significance) The organizations and their departments joined under this program was divided into projects in a way that through working together, they are able to meet the program objectives. Project No.1. Innovative power electronic technologies for increasing energy efficiency of industrial and household sectors in Latvia, future power supply grids and harvesting of renewable resources. The results achieved within the project are relevant to the stated objectives and are targeted towards achieving the main and specific goals of the project. Various technological solutions have been elaborated for deploying DC micro-grids in industrial or household objects - power converters for integration of energy storage and PV panels into DC micro-grid, interfacing the DC micro-grid to AC distribution grid, as well as a DC grid emergency tripping device. A prototype of multi-channel measurement system for detailed monitoring of electrical energy flow has been developed and approbated in two industrial sites. Technological solutions and power converter prototypes have been developed for reactive power control in order to increase energy efficiency of industrial objects, for charging and managing electrical vehicle batteries, for increasing energy efficiency of electrical drive systems with braking energy recuperation, as well as for harvesting wind energy. The project results have been published in scientific publications and presented in international scientific conferences, as well as in popular science seminars. The scientific group of the project has strengthened the collaboration with “Daimler AG” (Germany), as well as with researchers from several foreign universities. Several developments of the project have been demonstrated in industry exhibitions in Latvia and Germany. Technical recommendations have been developed and handed in to industrial partners, as well as to state and local government authorities. The performance indicators set for the project have been achieved or overachieved in the majority of the positions. Within the second and third period of the project implementation, the elaboration of various device prototypes was encumbered by significant reduction in the allocated project budget in respect to the budget prescribed in the project application, which was compensated for within the last period, resulting in larger number of developments. Several journal publications have been prepared using the experimental data from the latest developments of the project and are expected to be published after the reviewing process will be completed in year 2018 and 2019. Project No. 2 Optimization of power system development planning, energy production, selling and distribution. The activities performed include a discussion and analysis of the methods for solving power system mode optimization problem for formulating the tasks: optimal control of the power supply process; synthesis and checking of control algorithms and software; P-4 development of an algorithm and software for the feasibility study; development of life cycle estimation algorithms for powerful transformers; analysis and development of the energy demand, generation and price forecasting methods and software tools.  The number of publications considerably exceeds the planned amount.  11 doctoral theses have been defended.  Significant scientific and practical results have been achieved, which have enabled the performance or submission of projects that are important for Latvia and the European Union. The attracted funds exceed the expenses of project No. 2 more than four times.  The developed software is being used industrially. The results were used Republic of Latvia.  The developed software complex “Software for diminishing electricity prices in the power system and simulation, control and development planning of the power system” has been distinguished with a diploma from the Latvian Academy of Sciences as the most important achievement in the science of Latvia in 2017 in the field of applied science. Project No. 3 Sustainable climate policy and innovative, energy efficient technological solutions (KPIET). The research carried out during the project, which was done in accordance with the objectives of the program, contributes to the development of the Latvian energy sector and its contribution to its growth, moving towards the development of a small-scale carbon policy and solutions. Research results have been published in more than 150 scientific publications, incl. internationally highly quoted journals indexed in SCOPUS and Web of Science databases, which highlight the scientific significance and investment in promoting the program. Within the framework of the project, nine scientific collective monographs have been published - "Modeling of Road Transport Policies in Latvia", " Sustainable Energy Sources", "Energy Efficiency in Buildings: Yesterday, Today and Tomorrow", "Energy System Analysis and Modeling", "Climate Engineering and Policy", "Energy Planning Development Trends in Local Governments of Latvia","Analysis of Industrial Energy Policy", "Production Efficiency. In the Place of Morning Coffee" and"Ecodesign Solutions for Climate Technologies". The results of research included in the monographs are of great practical importance as they provide new knowledge for a wide range of stakeholders - sectoral specialists, production company employees, policy makers, local government specialists, scientists, students, members of higher eduaction institutions, and others. Within the framework of the project, research was carried out in 15 activities. A new computer simulation model has been created for the planning of sustainable energy sector development by 2050, which allows analyzing various policy instruments and assessing their impact on the achievement of national energy and climate objectives. In the transport sector, a new mathematical model of energy-economy simulation has been developed for the analysis of a national carbon-reduction policy. Research in the field of renewable energy sources has been carried out in three directions: technological solutions for creating solar panel elements for energy efficiency have been developed; the potential of exploiting algae in the production of biogas and other high value added products has been assessed; gasification of biomass in the simultaneous production of electricity and heat was studied. The analysis of the implementation of the fourth generation heat supply system in the municipalities of Latvia was carried out in the P-5 study of district heating. In the field of building energy efficiency, new technological solutions for insulation of buildings have been developed and new financing schemes for the reconstruction of residential buildings have been proposed, proposals and recommendations for improvement of legislation (including the Law on Energy Efficiency), professional and public awareness campaigns and campaigns have been developed. In the context of regional development planning, mapping of carbon small- scale solutions and assessing the availability of bio-resources are made. In the context of sustainable development, the system dynamics model analyzes the adaptation of innovative technologies in the energy sector and, as an example, created an innovative climate technology for electricity production. A methodology for assessing the critical infrastructure's resilience was developed to fully prepare for and adapt to climate change. In energy planning of local government has been developed a methodology for assessing the potential for the transition to a small-scale carbon economy by introducing energy management. To analyze energy efficiency potential in the industry by introducing energy management, a system dynamics modeling tool has been created, the practical application of which has been demonstrated during the development of regulations of the Cabinet of Ministers of the Republic of Latvia. An analysis of the aspects of the efficient use of bio-resources has also been carried out in order to move towards a circular economy and produce high added value products; an eco-design concept has been developed, evaluated from two points of view - product and company, and developed a methodology for evaluating industrial symbiosis, obstacles to the introduction of intermediate- driving forces and incentive mechanisms. Throughout the project, information flow feedback was provided to the public through participation in seminars, summer schools, conferences, lectures, exhibitions, and more. in the events related to informing the public, during which every interested person could find out the information of interest to him, thereby gaining a better understanding of the topic. It should be noted that the program was popularized as such. Project No. 4 The innovative technologies of hydrogen and bio-fuel production, storage, quality control, quality providing and use in Latvia. The research has been done on the synthesis of biodiesel using low quality vegetable oils containing fatty acids in the presence of a new acid heterogeneous catalyst, on the synthesis of biodiesel without synthesis of glycerol through the intresterification of rapeseed oil, on the development of high added value products from glycerol by catalytic oxidation with oxygen or air and on the catalytic pyrolysis of biomass in order to obtain high quality bio-oil. The influence of structure of monoesters on the proceeding the interesterifications reactions and the influence of various catalysts on the interesterification and pyrolysis process of biomass was studied. In order to increase liquid biofuel production yields from lignocellulosic biomass, accordant biochemical and thermochemical technologies development and assessment was performed. Several activities were related to assessment of the most effective mechanical pre-treatment, product purification and concentration and product analysis. The results include the development of new methodologies for biodiesel synthesis, new catalysts and new methodologies for the selective oxidation of glycerol. Assessment of lignocellulosic biomass has allowed estimating the optimal biomass size and designing a technology for efficient application of membranes for product purification and concentration. The extraction of hydrogen in dark fermentation from corn silage, which was pre-treated with microorganisms, is done. It was found that the Trichoderma fungus increase P-6 hydrogen release. The studies are done on biohydrogen binding ability in metal hydrides without and with a polymeric shell, and it is found that hydride-forming metals activate the release of hydrogen in the dark fermentation process, and from tested metals and alloys most hydrogen binds to the palladium. Research has been carried out on biohydrogen enrichment in fermentation reactor using a metal hydride modified porous ceramic tube. New anode materials for photocatalytic splitting of water (TiO2 nanotubes, TiO2 with sulfur and nitrogen as impurities, Fe2O3, Y: Fe2O3 and TiO2- NiFe2O4 composite system) were studied. New materials with increased light absorption in visible light and increased photocurrent and photocatalytic activity were obtained. Based on the first principles, it is calculated how the TiO2 nanotubes' photocatalytic activity is affected by sulfur and nitrogen atomic impurities. It has been shown that the energetic parameters of electrons (the width of the forbiden gap) are rapidly changing as Ti co-ordination change, and the narrower gap is in the coordination sphere 2. The planar electrochemical cell was constructed for the determination of the thermoelectric effect in a mutually insoluble system of two liquids and the results for the water/diethyl ether system were obtained at a temperature difference of 0-50 degrees. Prepared reports on autonomous energy supply systems for the storage of solar and / or wind energy with hydrogen as energy carrier, on hydrogen safety and methods of hydrogen storage, and on public perceptions of hydrogen technologies. An analysis of policy documents and standards for filling stations for gaseous fuels was carried out. The obtained results are published in several scientific articles and presentation of the results in mass media is done. Summarized information on gaseous hydrogen detectors, materials and principles used for the determination of hydrogen in an environment. The planned results have been achieved. Project No. 5 Development of tools and assessment of energy and climate policy impact. During the project it was created the new version of the MARKAL-Latvia optimisation model which includes following new developments: (1) improved within the model the description of electricity consumption and supply patterns to provide comprehensive analysis of consumption-supply pattern in different time periods in annual terms, (2) improved algorithm for modelling electricity import-export flows to provide the inclusion of the impact of international power networks in energy sector development scenarios, (3) further development of the technological-economical data base of the model which describe both existing Latvian energy supply-consumption system and available in future energy production and consumption technologies. To describe the electricity flows between the different price areas within the model adequately, for each annual fraction distribution the Nord Pool Spot electricity weighted average price is calculated. The specific procedure/algorithm has been developed for the determination of differences in annual distribution of imported electricity price. In order to further model the complex development scenario of the Latvian energy supply - demand system by taking into account the targets of the EU and Latvia 2030 policy framework for energy and climate, the measures that are applicable and can be implemented in Latvia for emissions reduction in the energy sector were defined and described with algorithms in the model. The measures are described pointing out their potential in emissions reduction and the total costs for the measures implementation, including investments in launching new technologies, operational costs, etc. The model P-7 defines the more than 30 emissions reduction measures in transport, manufacturing, residential and service and energy transformation sectors. Important for Latvia GHG emissions reduction instruments in the energy sector to reach the 2030 targets in Latvian climate policy have been analysed. The following instruments applied for GHG emissions reduction in the energy sector both in Latvia and EU member states were analysed: normative regulatory instruments; fiscal and economic instruments; instruments for ensuring communication with the target groups. In each of the above, specific instruments and their basic principles of application were identified. A longlist of instruments was developed on the basis of experience in the EU countries. The main problems and obstacles that limit the application of different instruments in Latvia and their impact upon the GHG emissions amount were analysed. Ex-post assessment of the energy sector policy impact upon Latvian climate policy and Final energy consumption has been carried out for two cases by using the MARKAL- Latvia model. Within the framework of the project, based on the analyses of academic and applied research literature about the theme, a methodology was developed for the evaluation of the security of Latvian energy supply system and a proposal for the energy supply security indicator system and particular indicators it should comprise was prepared. In accordance with the overall concept of the research, it was evaluated and compared the values of the particular security indicators in the base year and in modelled scenarios for the year 2030. Thus, the security evaluation may serve as one of the arguments of the grounds for implementing a definite scenario. Modelling and analysis of Latvia energy system alternative development scenarios (2015 – 2050), including the energy and climate policy targets in the scenarios’ definition, are performed. As the results of modelling, the GHG emissions amount, specific costs of GHG emissions reduction in energy sector, energy saved due to implementation of energy efficiency measures, fuel distribution by types and other indicators characterising energy sector are evaluated. Concluding, the modelling of scenarios set has proved scientific relevance of the improvement and application of MARKAL-Latvia modelling tool, as it provides wide perspectives of application of modelling methodology for both academic research and elaboration and evaluation of Latvia energy and climate policies. Project No. 6 Complexes research on renewable energy production and utilization for innovative technologies use and investigation of biogas production potential in the waste recycling sector. The activities carried out include innovative technology investigations for solar energy use for cooling and heating, the assessment of renewable energy potential for electricity production by 2025, and RES potential evaluation, the research on long-term biomass energy potential estimation and analysis of the optimal biomass resources used for energy production, the research on different types of biomass emissions assessment in the various biomass utilization processes for energy production, the determination of the emission characteristics of fuel materials (RDF and SRF) from waste and their comparison with wood chips in Latvian boiler houses, the improvements on the production methodology of PV solar cell, analysis of wind parks operational effectiveness in Latvia, the development of optimization methodology for switched reluctance machine, the performance analysis of biogas plant in Latvia, the assessment P-8 of the potential of biogas production from suitable biomass, optimization studies of anaerobic fermentation process, efficiency of various additives (microelements, enzymes). The main results are published in 40 scientific articles, participation in 26 international conferences and workshops, organized 2 workshops, participation in the exhibition. Registered 2 LV patents. In the framework of the program defended 4 master's thesis and 2 doctoral thesis. The IPE researchers participated in the results achieved within the framework of the study by the Ministry of Economics. The study was approved by the Ministry of Economics and successfully submitted to the EC. NRP 6.1 project scientists developed and submitted to the Ministry of Environmental Protection and Regional Development an addendum contained in the Cabinet of Ministers regulations on the use of EU Structural Funds for the development of waste incineration requirements. In accordance with the plan all the required tasks have been completed. Complex research on innovative technologies for energy production and utilization from renewables could be used for optimal selection of equipment for fuel and energy use in the future, for development of well-balanced energy production and consumption systems. Results of investigations and their continuation in the future will make a significant contribution not only to the energy sector, especially for development of RES, but also to Latvian national economy. 1.9. Results of the programme * Results Performance indicator Planned** Achieved Scientific performance indicators 1. Scientific publications: 232 430 number of original scientific articles 64 78 (SCOPUS)(SNIP>1) number of original scientific articles 69 138 (SCOPUS)(SNIP<1) number of original scientific articles 81 183 SCOPUS and other proceedings of conferences included in international data bases number of original scientific articles in 17 28 journals of the database ERIH (A and B) or in proceedings of conferences number of reviewed scientific 10 10 monographs 2. In the framework of the program: 184 227 number of defended doctoral thesis 29 40 number of defended master's thesis 124 157 number of defended bachelor’s thesis 31 30 3. Elaborated methods for - - establishment of epigenetic effects of selected species under certain biotic and abiotic conditions 4. Developed in vitro system for - - cultures in order to conserve protected species P-9 Results Performance indicator Planned** Achieved Scientific performance indicators 5.Number of projects submitted to 11 16 Horizon 2020 6. Reports to authorities executing 50 35 policies Performance indicators of the promotion of the programme 1. Interactive events to promote the 320 494 process and results of the programme. Target groups should include students and the number of: conferences 86 189 seminars 44 56 organized seminars 53 72 popular-science publications 52 71 public lectures 13 14 events at schools 36 44 exhibitions 36 48 2. Press releases - - 3. Number of events to inform industry, 49 31 state and municipal organizations, involved in achieving objectives of the program 4.Public understanding on the field of 86 63 the program and support to public investment for implementation of the program (number of target groups involved) 5.Publicly accessible data at home - http://latenergi.rtu.lv/ pages of program implementers index.html At specific part of RTU’s home page dedicated to the program, information will be updated at least once in three months. Implementers of the program will ensure information and publicity events of separate projects according to publicity plans of each project. Economic performance indicators 1. Amount of private funding attracted 202 000 EUR 2 128 632 EUR to the scientific institution in the framework of the programme, including: 1.1. co-funding from the private sector - - to implement the projects of the programme P-10