As a result of government restrictions and travel bans due to the coronavirus (COVID-19) pandemic, the ETN Board decided to cancel our face-to-face Annual General Meeting (AGM) & Workshop, planned to take place on 30 June and 1 July 2020 in Amsterdam. In order not to delay the AGM further, we decided to hold our first-ever entirely virtual AGM & Workshop.
Virtual AGM & Workshop Week: 29 June – 3 July 2020
Our Annual General Meeting (AGM) took place on 30 June 2020, divided into two parts:
AGM: Opening and President’s speech, ETN’s annual report of activities and achievements, strategy discussion, financial report and ETN Board election results
AGM panel session: “Research and innovation challenges for gas turbines in a low-carbon world” with speakers from the European Commission, Total, Shell and Enel.
ETN’s Workshop consisted of four individual two-hour sessions:
29 June 2020: Additive manufacturing and new materials
1 July 2020: Gas turbines operational and fuel flexibility
2 July 2020: Next generation power cycles
3 July 2020: Condition monitoring and asset management for energy transition
ETN’s Young Engineers Committee held their first official meeting on 6 July 2020. This meeting, open to all ETN members, provided an opportunity for both “young engineers” and senior representatives of ETN member organisations to discuss the benefits each organisation is expecting from this new initiative. More details are available here.
ETN Board election
The new ETN Board of Directors was elected by the General Assembly. Read more about the election results here.
The resumes of the Board member candidates are available here (login required).
Activity Update 2019-2020
The ETN office has prepared our annual ETN Activity Update, which presents the key activities that have taken place since the last AGM in Pau, France, in March 2019. You can download the full report here (login required).
All presentations are available only for ETN members (login required).
ETN co-organised the webinar “Energy Efficiency – Unlocking the Potential of Unused Heat & Cold in Industry” on 26 June 2020, together with EUTurbines, A.SPIRE and the EU SET Plan Action 6 Secretariat, as part of the EU Sustainable Energy Week. In line with discussions on Heat and Cold in the EU Strategic Energy Technology (SET) Plan Action 6, which aims at “making EU industry less energy and resources intensive, more carbon-neutral and competitive“, the webinar addressed the potential of heat-to-power solutions and discussed how improved industrial energy efficiency contributes to the EU’s energy and climate targets.
Full recording of the webinar can be accessed here.
The OMSoP project, co-funded by the European Union’s 7th Framework Programme for Research and Development aims to provide and demonstrate technical solutions for the use of state-of-the-art concentrated solar power system (CSP) coupled to micro-gas turbines (MGT) to produce electricity. The intended system will be modular and capable of producing electricity in the range of 3-10 kW.
In February 2013, the OMSoP project kicked off with 8 partners from 5 countries with a total budget of 5,8 million euro. Successful dissemination and implementation of the project results should result in the demonstration of the stand-alone-system, addressing the key innovation bottlenecks: the high temperature solar receiver, the stand-alone solar dish concentrator and the more reliable micro-gas turbine.
This project has received funding from the European Union’s Seventh Programme for research, technological development and demonstration under grant agreement No 308952
Optimised Microturbine Solar Power system
FP7-ENERGY.2012.2.5.1:RESEARCH, DEVELOPMENT AND TESTING OF SOLAR DISH SYSTEMS
Acronym: OMSoP
Collaborative Project: FP7-308952
Duration: 4 years (2013-2017)
Budget: 5.8 M Euro (4.2 M Euro EU funding)
Co-funded by the European Commission, Directorate-General for Energy
OMSoP Sharepoint
Consortium Members can access the OMSoP project’s sharepoint platform here. The ETN Office can be contacted in case of issue with access credentials.
The overall objective of this project is to provide and demonstrate technical solutions for the use of state-of-the-art concentrated solar power system (CSP) coupled to micro-gas turbines (MGT) to produce electricity. The intended system will be modular and capable of producing electricity in the range of 3-10 kW. The aim is to make such a system available to provide energy needs for domestic and small commercial applications. For larger energy needs, the units can be stacked by virtue of their modular nature. It can be integrated with medium and long term energy storage and/or co-firing with conventional fuels. The primary technical challenge is to enable the production of small scale cost effective, efficient, reliable and easy to maintain units.
To achieve these objectives, research and development will be conducted in all aspects of the system leading to a full scale demonstration. The parabolic dish concentrator technology will be improved to reduce weight, improve tracking system and increase concentration ratio. A receiver suitable for this application will be optimised. This requires the development of absorption materials and improving heat transfer and cooling technology. A novel feature of this project is the replacement of the Stirling engine which is typically used in this size of application, to convert thermal energy to mechanical power, with an MGT. Stirling engines suffer from problems such as high cost, complexity and poor reliability. A recently developed MGT will be optimised in conjunction with the CSP system. The demonstration activity will focus testing on the primary components. Although thermal storage and hybridisation with other fuels are beyond the scope of this project in terms of demonstration, they will be considered in the overall system optimisation from both technical and economic points of view.
The Energy and Transport (ET) research centre comprises those areas of research focussed upon improving the efficiency of transportation, compression and energy-generation processes. The ET centre is formed from the following groups: Energy Systems & Engines, Aeronautics & Air Transport, Positive Displacement Compressors and Computational Fluid Dynamics.
In the OMSoP Project, City, University of London will act as scientific coordinator and will lea the micro gas turbine desgin and testing. They will also participate in system modelling, integration and demonstration.
University Roma Tre is the second largest University in Rome. About 36000 students are enrolled in eight Departments covering humanistic, scientific and technical fields.
In the OMSoP project, the Research Group of Fluid Machinery and Energy Conversion Systems is involved in the design of advanced solar receivers integrated with short-term storage systems, in the system analysis and plant techno-economic optimization.
The Italian National Agency for new technologies, energy and sustainable economic development is a public undertaking operating in the fields of energy, environment and new technologies to support competitiveness and sustainable development.
In the OMSoP project, ENEA will be involved as WP2 leader, where, in collaboration with other partners, will deal with modeling and simulations of solar unit and will contribute to the design of the integrated system. ENEA will conceive and study the plant layout in order to define the best option in terms of overall thermal efficiency and cost. ENEA will be involved in the realization of the demonstration plant, which will be assembled at ENEA Casaccia Research Center in Rome with the main objective of demonstrating the system full functionality and controllability.
Innova is specialized in the fields of solar concentration and of conversion of heat into power through efficient methods.In the OMSoP project, INNOVA will be responsible for the design and build of the solar dish
Compowers mission is to develop, manufacture and sell microturbines in the power range below 30 kW. It has among other things designed and built a 5 kW system which is now being tested.
In the OMSoP project, Compower will primarily work with development of the microturbine for the demonstrator and with the microturbine aspects in the techno – economic analyses and optimization. Compower will also be engaged in the market analysis work.
The division of Heat and Power Technology (HPT) at the Royal Institute of Technology, conducts research in the field of poly-generation (combined production of electricity, heat, cooling, clean water, fuel, etc.), stationary flows and aeroelasticity of turbo machinery, concentration solar power and use of biofuels in gas turbine cycles (gasification and combustion technologies).
In the OMSoP project, HPT will develop high temperature solar receivers that will be tested and validated in the division’s high-flux solar simulator together with the micro-turbine.
In the OMSoP Project, The university of Seville will develop the market and cost analysis of the OMSoP generator in order to make it cost-competitive and to identify the potential niche markets in which the system is likely to have a significant impact on the power generation sector.
ETN is a non-profit association bringing together the entire value chain of the gas turbine technology community in Europe. Through the co-operative efforts of our members, ETN facilitates gas turbine research and technology development, promoting environmentally friendly gas turbine technology with reliable and low cost operation.
In the OMSoP project, ETN will be responsible for the dissemination of the project results.
The technical challenges being addressed by the OMSoP project are divided into 3 Work Packages:
WP1 System Component Development
There are two main tasks for the WP1. The first is to develop and separately test the components for a demonstration system in the range of up to 10kWe. The micro gas turbine will be based on improvements to an existing system developed by Compower. Development and testing will be conducted at City University London. KTH will develop and test a receiver in their Solar Lab while INNOVA will develop a solar concentrator based on their solar dish-Sterling technology. The second task is to use the acquired knowledge to develop components for an optimised microturbine solar dish system for the power range up to 30kWe for future testing and deployment.
WP2 System design and integration
This WP has two main tasks. The first is to integrate the system demonstration components developed in WP1 and perform the tests for the overall system. Data obtained will be used to inform the optimised system design which is the subject of the second task. The second task will coordinate the development of the optimised system components from WP1 and the techno-economic information from WP3 to produce a final design for an optimum system for future testing and deployment.
WP3 Techno-Economic analysis
Thermodynamic and mechanical models of the system and its components will be developed and used for the analysis and design of both the demonstration system and optimised system in WP2. Further insight into future deployment will be gained by investigating concepts such as medium and long-term storage, hybridisation with other fuels and MGT power augmentation concepts. Market and cost analyses will also be performed in addition to uncertainty, sensitivity and risk studies. The above will provide crucial information to system and component development and will also provide insight into potential future deployment. Finally, a life cycle assessment will be performed to evaluate the environmental aspects and potential impact associated to the solar system.
The project aims to conduct flow-sheeting, industrial scale-up, safety and economic analysis, to improve the fundamental knowledge and efficiency of the S_I cycle H2 production step, and to investigate a solar primary energy source for the H2SO4 decomposition step which is common to both cycles.
The Project aims to promote the exploitation of concentrated solar energy through small and middle scale facilities. The project is particularly relevant to local requirements of power and heat. A back-up with the locally available renewable fuels available locally or those which can be easily produced. The project will include testing the CSPtechnology in cites with favourable solar insolation.
The general project objective is to assess and to develop an innovative (TES) concept having the best potential to provide efficient, reliable and economic energy storage for CSP plants. The experimental programme (will focus on the full development of the integrated system, up to demonstration level.
The DiGeSPo project aims to research and build a modular 1-3 kWe, 3-9 kWth micro Combined Heat and Power (m-CHP) system based on innovative Concentrated Solar Power (CSP) and Stirling engine technology. This CSP m-CHP unit will provide electrical power, heating and cooling for single and multiple domestic dwellings and other small commercial, industrial and public buildings. It integrates small scale concentrator optics with moving and tracking components, solar absorbers in the form of evacuated tube collectors, a heat transfer fluid, a Stirling engine with generator, and heating and/or cooling systems.
ETN is still very much active despite the unprecedented global COVID-19 crisis and is here to help our members in any way we can. The ETN Board has decided to hold regular biweekly teleconference meetings to ensure the best governance in these challenging times.
As a result of the pandemic, we have been forced to postpone ETN meetings and events scheduled for this spring. The ETN office and the Board are monitoring the situation closely, following the recommendations by the World Health Organisation, the European Centre for Disease Prevention and Control and the local governments. The safety of ETN members is our highest priority, and we will take any necessary precautions to mitigate risks.
Due to the uncertain situation, ETN has changed its policy for registrations and sponsorships for all our events. In case any of the ETN events would be 1) postponed –> the sponsorship would be moved to the new date, or 2) cancelled –> the sponsor would be entitled to a full refund. With regard to event registrations, registered delegates would have the choice to keep their registration if the event is postponed or to ask for a refund.
ETN’s postponed Annual General Meeting & Workshop, now planned to take place on 30 June – 1 July 2020 in Amsterdam, is still scheduled for these dates, but a plan B is currently under development in case the situation remains too uncertain, or if the Dutch government announces prolonged measures in the upcoming months.
ETN’s LM2500 User Group Meeting, scheduled for 2-4 June 2020 in Aberdeen, is still set to take place as planned, but we are evaluating the possibility to postpone the event to the first week of September if needed. Our SGT-A35 User Group Meeting has been postponed to November 2020 and the exact dates will be communicated in the coming month. Our 10th International Gas Turbine Conference is still set to take place in Brussels on 14-15 October 2020.
In the meantime, until it is safe again to organise normal meetings and events, ETN’s Working Groups and projects are still moving forward and continue their activities using online meeting tools and platforms.
In order to help our members to overcome challenges in these difficult times, the ETN office has decided to develop a new section for the ETN website where our members can submit requests or problems of any type, and where other members are invited to provide their help and possible solutions for these issues. If you have any issues that you would like to raise or discuss with the global turbomachinery community, we are here to help you – please don’t hesitate to contact us. More details will be available for our members in our upcoming Monthly News Summary.
ASME Advanced Manufacturing & Repair for Gas Turbines (AMRGT) Conference will take place on 3-4 March 2020 in Charlotte, North Carolina, US.
ASME AMRGT is the only event in the industry dedicated solely to advanced manufacturing for gas turbines. This user-focused conference will share best practices and new technologies on how to successfully implement advanced manufacturing techniques to improve efficiencies and reduce maintenance costs within their operations. Join the event to learn, share and build relationships with the full supply chain of companies involved with advanced manufacturing for gas turbines, all under one roof.
ETN members are entitled to a discounted registration fee for this event. Please contact us for more details: nk[at]etn.global
More information about the event is available here.
The ETN Hydrogen Gas Turbines report – “The path towards a zero-carbon gas turbine” was published as part of the activities of ETN’s Hydrogen Working Group.
European Utility Week and POWERGEN Europe took place in Paris, France, on 12-14 November 2019.
ETN’s Managing Director Christer Björkqvist chaired the Hub Session “Gas turbines in a carbon-neutral society” on the opening day. All presentations from this session are available for ETN members (requires login).
ETN’s annual High-Level User Meeting was held on 30 September 2019 at AC Hotel by Marriott Firenze. For more information on the meeting, please click here.
CAB meeting
The Conference Advisory Board of ETN’s IGTC-20 met in the morning on 1 October at Florence Learning Center.
Documentation
All presentations and the Workshop Summary Report are available only for ETN members (requires login).
ETN’s High-Level User Meeting “Operational optimisation strategy and technology development needs for a low carbon society” was held on 30 September at AC Hotel by Marriott Firenze, in conjunction with ETN’s October Workshop.
At this user-only meeting each user presents 1-3 technical issues to be solved or technical development requirements to be discussed. It is an excellent occasion to exchange views and experiences with senior-level users from the oil & gas, utility and industry sectors, and to bring forward short-and long-term turbomachinery development needs that will have an important impact on the profitability of the operations and fulfilment of the users’ long-term strategies.
The OMSoP project, co-funded by the European Union’s 7th Framework Programme for Research and Development aims to provide and demonstrate technical solutions for the use of state-of-the-art concentrated solar power system (CSP) coupled to micro-gas turbines (MGT) to produce electricity. The intended system will be modular and capable of producing electricity in the range of 3-10 kW.
