Innovating Works

H2020

Cerrada
HORIZON-JTI-CLEANH2-2023-...
HORIZON-JTI-CLEANH2-2023-03-03: Ultra-low NOx combustion system for aviation
ExpectedOutcome:The use of hydrogen as an aviation fuel allows to eliminate the direct CO2 emissions from aircraft engines completely and thus offers the potential to contribute substantially to the ambition of a net-zero carbon emission aviation as defined in Waypoint 2050[1], and to the European goal to “go climate neutral” by 2050 as described in the European Green Deal. Of the available technologies and the targeted market ranges, a direct burn hydrogen combustion system for the short- and medium-range market will be the preferred configuration because currently 67 % of the global CO2 emissions from aviation are being emitted by 70 % of the global fleet in this segment while only 30 % of the global CO2 emissions are being emitted by long-range wide-body turbofan engines and only 3 % of the global CO2 emissions are being emitted by regional jets (Hydrogen-powered aviation study, p. 16)[2] to which hydrogen fuel cells are currently limited because of their relatively low energy density. Therefore, direct burn hydrogen combustion systems applied to the short- and medium-range market will play the dominant role in decarbonising aviation by using hydrogen as a fuel.
Sólo fondo perdido 0 €
Europeo
Esta convocatoria está cerrada Esta línea ya está cerrada por lo que no puedes aplicar. Cerró el pasado día 18-04-2023.
Se espera una próxima convocatoria para esta ayuda, aún no está clara la fecha exacta de inicio de convocatoria.
Hace más de 20 mes(es) del cierre y aún no tenemos información sobre los proyectos financiados, no parece que se vaya a publicar esta información.
Presentación: Consorcio Consorcio: Esta ayuda está diseñada para aplicar a ella en formato consorcio..
Esta ayuda financia Proyectos:

ExpectedOutcome:The use of hydrogen as an aviation fuel allows to eliminate the direct CO2 emissions from aircraft engines completely and thus offers the potential to contribute substantially to the ambition of a net-zero carbon emission aviation as defined in Waypoint 2050[1], and to the European goal to “go climate neutral” by 2050 as described in the European Green Deal. Of the available technologies and the targeted market ranges, a direct burn hydrogen combustion system for the short- and medium-range market will be the preferred configuration because currently 67 % of the global CO2 emissions from aviation are being emitted by 70 % of the global fleet in this segment while only 30 % of the global CO2 emissions are being emitted by long-range wide-body turbofan engines and only 3 % of the global CO2 emissions are being emitted by regional jets (Hydrogen-powered aviation study, p. 16)[2] to which hydrogen fuel cells are currently limited because of their relatively low energy density. Therefore, direct burn hydrogen combustion systems applied to the short- and medium-range market will play the dominant role in decarbonising aviation by using hydrogen as a fuel.

Mor... ver más

ExpectedOutcome:The use of hydrogen as an aviation fuel allows to eliminate the direct CO2 emissions from aircraft engines completely and thus offers the potential to contribute substantially to the ambition of a net-zero carbon emission aviation as defined in Waypoint 2050[1], and to the European goal to “go climate neutral” by 2050 as described in the European Green Deal. Of the available technologies and the targeted market ranges, a direct burn hydrogen combustion system for the short- and medium-range market will be the preferred configuration because currently 67 % of the global CO2 emissions from aviation are being emitted by 70 % of the global fleet in this segment while only 30 % of the global CO2 emissions are being emitted by long-range wide-body turbofan engines and only 3 % of the global CO2 emissions are being emitted by regional jets (Hydrogen-powered aviation study, p. 16)[2] to which hydrogen fuel cells are currently limited because of their relatively low energy density. Therefore, direct burn hydrogen combustion systems applied to the short- and medium-range market will play the dominant role in decarbonising aviation by using hydrogen as a fuel.

Moreover, in addition to the decarbonisation initiatives, increased focus has recently been put on non-CO2 emissions, especially NOx, in order to drive for climate neutrality. Therefore, without the development of specialised ultra-low NOx combustion technologies, direct burn hydrogen combustion systems are prone to experience higher NOx emissions than current, state-of-the-art combustion systems operated with Jet-A1 because of higher flame temperatures and the high reactivity of hydrogen when burnt in air. Increased NOx emissions would have a global warming effect from non-CO2 emissions and would impact the local air quality around airports which would endanger the acceptance of direct burn hydrogen combustion systems and thus would limit its ability to utilise the available decarbonisation potential. The development of ultra-low NOx combustion technologies is then an essential requirement for direct burn hydrogen combustion systems.

Project results are expected to contribute to all the following outcomes:

deliver technologies for Airbus’ ZEROe game-changing concepts for future commercial passenger aircraft using hydrogen as the primary energy supply (Airbus ZEROe, 2022[3]) Project results are expected to contribute to the following objectives and KPIs of the Clean Hydrogen JU SRIA as well as to the following additional KPIs:

Low NOx emitting hydrogen turbinesDry low NOx emissions across all engine operating conditions at least as low as current state-of-the-art which is around 50% below regulation in force (CAEP/8).Dry low NOx technology with potential to reduce NOx emissions further by no less than 30% compared to state-of-the-art.
Scope:The scope of the topic is to develop a direct burn hydrogen combustion system with low NOx emissions compatible with aero engine specifications and progress it up to TRL 4. Because of the specific thermo-physical characteristics of hydrogen (very high flame speed, high diffusivity, high reactivity, high flame temperatures, etc.) there are many technological hurdles to overcome in order to realise a reliable and successful low NOx combustion system. The most difficult and important ones are:

Effective temperature control in the primary zone to avoid excessive thermal NOx productionReliable and safe ignition and flame stabilisation without autoignition and flash-backWide stability limits necessary to cover typical engine operating rangesNo overheating of flame holding and combustor structures (dome & liners)Control of thermoacoustic instabilities Therefore, the scope for the development of the low NOx combustion technology should include the following steps:

Development of a new innovative fuel injection system capable of creating a homogeneous fuel/air distribution, reliable and safe ignition, and flame stabilisation without autoignition and flash-back, no overheating of flame holding and combustor structures, and effective control of the NOx production across typical aero engine operating ranges;Demonstration of the low NOx technology in single cup tests with optical access and thermoacoustic measurement capabilities up to relevant operating pressures and temperatures (T3 = 950 Kelvin, P3 = 20 bar);Demonstration of the low NOx technology in multi-cup sector combustor tests with different thermoacoustic boundary conditions (open exit and exit restriction), and thermoacoustic as well as emission measurement capabilities up to relevant operating pressures and temperatures (T3 = 950 Kelvin, P3 = 40 bar);Demonstration of reliable and safe operation across relevant operating range (T3, P3, FAR: 950 Kelvin, 40 bar, at least 0.004 - 0.04) without flash-back, auto-ignition, blow-out, and over-heating of combustor hardware;Proof of thermoacoustic stability without excessive pressure amplitudes across relevant operating range;Contribution to development of EU competitiveness for low NOx hydrogen direct burn combustion technologies. The project should address the following requirements and specifications:

Reliable and safe combustor ignition at ground start conditions with 100% hydrogen;Lean blow-out within limits necessary for typical aero engine operation (FARLBO ≤ 0.004);Dry low NOx emissions across all engine operating conditions at least as low as current state-of-the-art which is around 50% below regulation in force (CAEP/8).Dry low NOx technology with potential to reduce NOx emissions further by no less than 30% compared to state-of-the-art.Operability and emission performance fulfilled for hydrogen temperatures in the range of 200 – 420 Kelvin;Efficient fuel/air mixing without flashback and autoignition across typical aero engine operating range;Temperatures of fuel injectors, dome, and combustor liners within limits for targeted engine life;Dynamic combustion pressures (P4) within limits for targeted engine life;Combustor length no longer than current state-of-the-art aero engine combustors. Proposals are expected to co-operate and seek synergies with the projects and activities of the Clean Aviation JU. In particular:

In Clean Aviation JU Phase 1, an existing turbofan engine will be adapted for the operation with 100% hydrogen and will be demonstrated in a ground test demonstrator in order to prove full system feasibility, starting from the liquid hydrogen tank, through the hydrogen fuel and control system including vaporiser/conditioner, up to the adapted combustor. The successful 100% hydrogen turbofan engine ground test demonstrator is a prerequisite for the planned flight test demonstrator, including contrails measurements by a chasing airplane, at the beginning of Clean Aviation JU Phase 2. Because of the very tight schedule and the challenging tasks in Clean Aviation Phase 1, only limited effort can be put on the development of a low NOx combustion technology (limited to residence time, mixing and dilution). On the other hand, the time in Clean Aviation JU Phase 2 will be too short to develop the low NOx combustion technology on time up to the TRL level necessary for the launch of a product development after Clean Aviation JU if no pre-development work has been performed in parallel to Clean Aviation JU Phase 1;Therefore, the development of the low NOx combustion technology is proposed to be performed in this topic up to TRL4 in order to be able to further mature the technology in Clean Aviation JU Phase 2 up to TRL 6. The low NOx combustion technology developed in the current project will be complementing the “conventional” hydrogen combustion technology developed for the early ground test demonstrator in Phase 1 of Clean Aviation JU. In order to exploit synergies between the two Work Programs, applicants are expected to exchange information with projects selected from the Clean Aviation JU call topic HORIZON-JU-CLEAN-AVIATION-2022-01-HPA-01[4]: ‘Direct Combustion of Hydrogen in Aero-engines’, including (but not limited to) engine and/or combustion chamber geometries and specifications, and forecast emissions profiles;The development activities in this topic should be closely aligned with the projection of a hydrogen direct burn innovation as defined in Clean Aviation JU in order to develop a targeted low NOx combustion technology for this application. Applicants are encouraged to address sustainability and circularity aspects in the activities proposed.

Activities are expected achieve TRL 4 by the end of the project - see General Annex B.

The JU estimates that an EU contribution of maximum EUR 8.00 million would allow these outcomes to be addressed appropriately.

The conditions related to this topic are provided in the chapter 2.2.3.2 of the Clean Hydrogen JU 2023 Annual Work Plan and in the General Annexes to the Horizon Europe Work Programme 2023–2024 which apply mutatis mutandis.


Specific Topic Conditions:Activities are expected achieve TRL 4 by the end of the project - see General Annex B.




[1]https://aviationbenefits.org/media/167187/w2050_full.pdf

[2]https://www.clean-hydrogen.europa.eu/media/publications/hydrogen-powered-aviation_en

[3]https://www.airbus.com/en/innovation/zero-emission/hydrogen/zeroe

[4]https://ec.europa.eu/info/funding-tenders/opportunities/portal/screen/opportunities/topic-details/horizon-ju-clean-aviation-2022-01-hpa-01;

ver menos

Temáticas Obligatorias del proyecto: Temática principal:

Características del consorcio

Ámbito Europeo : La ayuda es de ámbito europeo, puede aplicar a esta linea cualquier empresa que forme parte de la Comunidad Europea.
Tipo y tamaño de organizaciones: El diseño de consorcio necesario para la tramitación de esta ayuda necesita de:

Características del Proyecto

Requisitos de diseño: Duración:
Requisitos técnicos: ExpectedOutcome:The use of hydrogen as an aviation fuel allows to eliminate the direct CO2 emissions from aircraft engines completely and thus offers the potential to contribute substantially to the ambition of a net-zero carbon emission aviation as defined in Waypoint 2050[1], and to the European goal to “go climate neutral” by 2050 as described in the European Green Deal. Of the available technologies and the targeted market ranges, a direct burn hydrogen combustion system for the short- and medium-range market will be the preferred configuration because currently 67 % of the global CO2 emissions from aviation are being emitted by 70 % of the global fleet in this segment while only 30 % of the global CO2 emissions are being emitted by long-range wide-body turbofan engines and only 3 % of the global CO2 emissions are being emitted by regional jets (Hydrogen-powered aviation study, p. 16)[2] to which hydrogen fuel cells are currently limited because of their relatively low energy density. Therefore, direct burn hydrogen combustion systems applied to the short- and medium-range market will play the dominant role in decarbonising aviation by using hydrogen as a fuel. ExpectedOutcome:The use of hydrogen as an aviation fuel allows to eliminate the direct CO2 emissions from aircraft engines completely and thus offers the potential to contribute substantially to the ambition of a net-zero carbon emission aviation as defined in Waypoint 2050[1], and to the European goal to “go climate neutral” by 2050 as described in the European Green Deal. Of the available technologies and the targeted market ranges, a direct burn hydrogen combustion system for the short- and medium-range market will be the preferred configuration because currently 67 % of the global CO2 emissions from aviation are being emitted by 70 % of the global fleet in this segment while only 30 % of the global CO2 emissions are being emitted by long-range wide-body turbofan engines and only 3 % of the global CO2 emissions are being emitted by regional jets (Hydrogen-powered aviation study, p. 16)[2] to which hydrogen fuel cells are currently limited because of their relatively low energy density. Therefore, direct burn hydrogen combustion systems applied to the short- and medium-range market will play the dominant role in decarbonising aviation by using hydrogen as a fuel.
Capítulos financiables: Los capítulos de gastos financiables para esta línea son:
Personnel costs.
Subcontracting costs.
Purchase costs.
Other cost categories.
Indirect costs.
Madurez tecnológica: La tramitación de esta ayuda requiere de un nivel tecnológico mínimo en el proyecto de TRL 4:. Es el primer paso para determinar si los componentes individuales funcionarán juntos como un sistema en un entorno de laboratorio. Es un sistema de baja fidelidad para demostrar la funcionalidad básica y se definen las predicciones de rendimiento asociadas en relación con el entorno operativo final. + info.
TRL esperado:

Características de la financiación

Intensidad de la ayuda: Sólo fondo perdido + info
Fondo perdido:
0% 25% 50% 75% 100%
Para el presupuesto subvencionable la intensidad de la ayuda en formato fondo perdido podrá alcanzar como minimo un 100%.
The funding rate for RIA projects is 100 % of the eligible costs for all types of organizations. The funding rate for RIA projects is 100 % of the eligible costs for all types of organizations.
Garantías:
No exige Garantías
No existen condiciones financieras para el beneficiario.

Información adicional de la convocatoria

Efecto incentivador: Esta ayuda no tiene efecto incentivador. + info.
Respuesta Organismo: Se calcula que aproximadamente, la respuesta del organismo una vez tramitada la ayuda es de:
Meses de respuesta:
Muy Competitiva:
No Competitiva Competitiva Muy Competitiva
No conocemos el presupuesto total de la línea pero en los últimos 6 meses la línea ha concecido
Total concedido en los últimos 6 meses.
Minimis: Esta línea de financiación NO considera una “ayuda de minimis”. Puedes consultar la normativa aquí.

Otras ventajas

Sello PYME: Tramitar esta ayuda con éxito permite conseguir el sello de calidad de “sello pyme innovadora”. Que permite ciertas ventajas fiscales.
HORIZON-JTI-CLEANH2-2023-1 Ultra-low NOx combustion system for aviation ExpectedOutcome:The use of hydrogen as an aviation fuel allows to eliminate the direct CO2 emissions from aircraft engines completely and th...
Sin info.
HORIZON-JTI-CLEANH2-2023-05-03 Pre-Normative Research on the determination of hydrogen releases from the hydrogen value chain
en consorcio: ExpectedOutcome:The EU’s Hydrogen Strategy[1], REPowerEU[2] and other relevant European initiatives, clearly recognise clean hydrogen and it...
Cerrada hace 1 año | Próxima convocatoria prevista para el mes de
HORIZON-JTI-CLEANH2-2023-07-02 Increasing the lifetime of electrolyser stacks
en consorcio: ExpectedOutcome:Hydrogen can be used as a feedstock, a fuel, an energy carrier in electrolyser technologies, and thus has many possible appl...
Cerrada hace 1 año | Próxima convocatoria prevista para el mes de
HORIZON-JTI-CLEANH2-2023-03-01 Real environment demonstration of Non-Road Mobile Machinery (NRMM)
en consorcio: ExpectedOutcome:Internal combustion engines (ICEs) in Non-Road Mobile Machinery[1] (NRMM) (e.g. diesel or gasoline fuelled) significantly co...
Cerrada hace 1 año | Próxima convocatoria prevista para el mes de
HORIZON-JTI-CLEANH2-2023-01-01 Innovative electrolysis cells for hydrogen production
en consorcio: ExpectedOutcome:Water electrolysis for hydrogen production is a mature and well-established technology with major industrial deployments sin...
Cerrada hace 1 año | Próxima convocatoria prevista para el mes de
HORIZON-JTI-CLEANH2-2023-01-07 Hydrogen use by an industrial cluster via a local pipeline network
en consorcio: ExpectedOutcome:Renewable hydrogen offers industry the means to decarbonise thermal and chemical processes that currently rely on fossil fue...
Cerrada hace 1 año | Próxima convocatoria prevista para el mes de
HORIZON-JTI-CLEANH2-2023-01-02 Innovative Solid Oxide electrolysis cells for intermediate temperature hydrogen production
en consorcio: ExpectedOutcome:Large scale sustainable hydrogen production is necessary to implement hydrogen as an energy vector in a future decarbonised...
Cerrada hace 1 año | Próxima convocatoria prevista para el mes de
HORIZON-JTI-CLEANH2-2023-01-06 Valorisation of by-product O2 and/or heat from electrolysis
en consorcio: ExpectedOutcome:Large scale economically viable hydrogen production is necessary to implement the ambition of the “Hydrogen Strategy for a c...
Cerrada hace 1 año | Próxima convocatoria prevista para el mes de
HORIZON-JTI-CLEANH2-2023-01-05 Waste to Hydrogen demonstration plant
en consorcio: ExpectedOutcome:The sustainable wastes management in Europe is an emerging issue of the circular economy due to the restrictions given by EU...
Cerrada hace 1 año | Próxima convocatoria prevista para el mes de
HORIZON-JTI-CLEANH2-2023-03-03 Ultra-low NOx combustion system for aviation
en consorcio: ExpectedOutcome:The use of hydrogen as an aviation fuel allows to eliminate the direct CO2 emissions from aircraft engines completely and th...
Cerrada hace 1 año | Próxima convocatoria prevista para el mes de
HORIZON-JTI-CLEANH2-2023-06-01 Large-scale Hydrogen Valley
en consorcio: ExpectedOutcome:A Hydrogen Valley typically require a multi-million EUR investment and cover all necessary steps in the hydrogen value chain...
Cerrada hace 1 año | Próxima convocatoria prevista para el mes de
HORIZON-JTI-CLEANH2-2023-06-02 Small-scale Hydrogen Valley
en consorcio: ExpectedOutcome:A Hydrogen Valley typically require a multi-million EURO investment and cover all necessary steps in the hydrogen value chai...
Cerrada hace 1 año | Próxima convocatoria prevista para el mes de
HORIZON-JTI-CLEANH2-2023-07-01 Advanced materials for hydrogen storage tanks
en consorcio: ExpectedOutcome:For hydrogen, as well as its derivatives, to be a truly sustainable energy vector and part of a future sustainable energy sy...
Cerrada hace 1 año | Próxima convocatoria prevista para el mes de
HORIZON-JTI-CLEANH2-2023-05-02 European Hydrogen Academy
en consorcio: ExpectedOutcome:The European Commission is placing skills at the heart of the policy agenda, steering investment in people and education and...
Cerrada hace 1 año | Próxima convocatoria prevista para el mes de
HORIZON-JTI-CLEANH2-2023-04-02 Research on fundamental combustion physics, flame velocity and structure, pathways of emissions formation for hydrogen and variable blends of hydrogen, including ammonia
en consorcio: ExpectedOutcome:Hydrogen is a potential enabler of a low-carbon economy and can be a key instrument for the European Green Deal and the rece...
Cerrada hace 1 año | Próxima convocatoria prevista para el mes de
HORIZON-JTI-CLEANH2-2023-02-01 Large-scale demonstration of underground hydrogen storage
en consorcio: ExpectedOutcome:Large-scale hydrogen storage has the potential to enable the integration of intermittent renewable energy sources in the gas...
Cerrada hace 1 año | Próxima convocatoria prevista para el mes de
HORIZON-JTI-CLEANH2-2023-02-02 Pre-Normative Research about the compatibility of transmission gas grid steels with hydrogen and development of mitigation techniques
en consorcio: ExpectedOutcome:This topic is aimed at accelerating the deployment of a safe, flexible, and efficient hydrogen grid by repurposing part of t...
Cerrada hace 1 año | Próxima convocatoria prevista para el mes de
HORIZON-JTI-CLEANH2-2023-02-05 Demonstration of LH2 HRS for Heavy Duty applications
en consorcio: ExpectedOutcome:The topic aims to develop and demonstrate the technological foundations of large LH2 refuelling stations for the heavy-duty...
Cerrada hace 1 año | Próxima convocatoria prevista para el mes de
HORIZON-JTI-CLEANH2-2023-03-02 Development of a large fuel cell stack for maritime applications
en consorcio: ExpectedOutcome:Hydrogen as fuel for the maritime sector could be pivotal to foster global maritime decarbonisation as it has significant ad...
Cerrada hace 1 año | Próxima convocatoria prevista para el mes de
HORIZON-JTI-CLEANH2-2023-04-01 Development and validation of high power and impurity tolerant fuel cell systems ready to run on industrial quality dry hydrogen
en consorcio: ExpectedOutcome:Hydrogen offers a unique chance to decarbonise the power generation and heating sectors reliably and independently from weat...
Cerrada hace 1 año | Próxima convocatoria prevista para el mes de
HORIZON-JTI-CLEANH2-2023-04-04 Hydrogen for heat production for hard-to-abate industries (e.g. retrofitted burners, furnaces)
en consorcio: ExpectedOutcome:When produced with renewable or low-carbon energy sources, hydrogen represents a unique opportunity for the decarbonisation...
Cerrada hace 1 año | Próxima convocatoria prevista para el mes de
HORIZON-JTI-CLEANH2-2023-04-03 Retrofitting of existing industrial sector natural gas turbomachinery cogeneration systems for hydrogen combustion
en consorcio: ExpectedOutcome:In the gas transmission systems, gas turbines in simple and combined cycles, can achieve a significant reduction of atmosphe...
Cerrada hace 1 año | Próxima convocatoria prevista para el mes de
HORIZON-JTI-CLEANH2-2023-02-04 Demonstration of high pressure (500-700 bar) supply chain
en consorcio: ExpectedOutcome:In order to contribute to the 2030 Climate plan and Green Deal, it is of the utmost importance to improve the Gaseous Hydrog...
Cerrada hace 1 año | Próxima convocatoria prevista para el mes de
HORIZON-JTI-CLEANH2-2023-01-03 Advances in alkaline electrolysis technology
en consorcio: ExpectedOutcome:At present, Europe has an industrial leadership on electrolyser technologies with about two thirds of main players globally....
Cerrada hace 1 año | Próxima convocatoria prevista para el mes de
HORIZON-JTI-CLEANH2-2023-02-03 Novel insulation concepts for LH2 storage tanks
en consorcio: ExpectedOutcome:An important element of the European Hydrogen Strategy is to support the deployment of LH2 for heavy duty applications and t...
Cerrada hace 1 año | Próxima convocatoria prevista para el mes de
HORIZON-JTI-CLEANH2-2023-05-01 Product environmental footprint pilot for a set of FCH product categories
en consorcio: ExpectedOutcome:Environmental sustainability of FCH systems is a key requirement in the path towards a hydrogen economy, with important effe...
Cerrada hace 1 año | Próxima convocatoria prevista para el mes de
HORIZON-JTI-CLEANH2-2023-01-04 Photoelectrochemical (PEC) and/or Photocatalytic (PC) production of hydrogen
en consorcio: ExpectedOutcome:Photo(electro)chemical systems have been identified as one of the promising technologies to meet long-term hydrogen-producti...
Cerrada hace 1 año | Próxima convocatoria prevista para el mes de