1. Introduction
To achieve the desired reduction in climate impact of the aviation sector, formulated by e.g., the European Commission’s Strategic Research and Innovation Agenda [
1], all available short and long-term options need to be taken into consideration. One of the short-to-midterm approaches could be the retrofit of existing aircraft with advanced propulsion technology to reduce the pressure of entirely new clean-sheet designs with their given financial risk.
In times of intense discussions on different propulsion system concepts for varying aircraft sizes and design ranges to reduce aviation’s climate impact, aircraft manufacturers are confronted with a large spectrum of available options. Next to the technological decision to be made on the powertrain configuration, and especially the energy source used, the decision on clean-sheet design or retrofit needs to be answered. For a small company as Deutsche Aircraft GmbH (DA) with its Dornier Do 328 (D328) aircraft, the retrofit approach enables the possibility to offer customers a more sustainable variant of the original product without the requirement of costly designing and certifying an entirely new product. Obviously, a retrofit will never be an entirely optimized product, but its advantages might outweigh the drawbacks by far if the correct requirements are put into place. This is especially valid if the service life of an aircraft can be substantially prolonged by fitting a new propulsion system.
Aircraft retrofits have been investigated for decades, as they are not only an option to broaden the spectrum of sellable products but are also a valuable possibility to generate test aircraft for system tests with existing equipment. One famous example of an early liquid hydrogen (LH
2) test in aviation propulsion is the Tupolev-155, built in the 1980s, which was a retrofitted Tupolev-154 with a cryogenic tank to burn different gases in modified engines [
2]. As it still used kerosene for two of the three engines, it was an early example of a dual-fuel retrofit. More recently, Universal Hydrogen demonstrated a single-side turboprop retrofit that displayed a hydrogen fuel cell (FC) rather than a hydrogen combustion engine [
3]. Nevertheless, as this aircraft features no built-in LH
2 tank but rather uses loadable containers as well as uneven propeller sizes, it is seen more as a flying system testbed. The importance of hydrogen FC-electric retrofits is underlined by companies, such as ZeroAvia [
4], specializing in aircraft retrofits only.
Retrofit studies have been performed on various propulsion system designs including battery-hybrid [
5,
6], pure FC-electric or pure hydrogen combustion (both [
7]), or conventional engine replacement [
8], and have also been assessed in terms of costs [
9]. Hydrogen produced from renewable energy is seen as one of the key enablers of the commercial aviation sector transition to climate neutrality, with an estimated global hydrogen aircraft market value of
$23.71 billion in 2030 already and a projection to reach
$144.53 billion by 2040 [
10]. Even though it has a potentially lower energy density compared to kerosene, depending on storage efficiency, hydrogen enables the integration of respective FCs. Nevertheless, the storage mass needs to be carried the entire mission, making the aircraft heavier than a purely kerosene-driven aircraft. Compared to the widely investigated use of batteries with their lower gravimetric energy density, hydrogen FCs require only one redox partner to be carried and reduce the fuel—and thus the mass—carried during the flight. Thermal management challenges arising due to the comparably low efficiency need to be tackled by an aerospace-tailored design of multiple components.
The project 328H2-FC, funded by the German Federal Ministry for Economic Affairs and Climate Action under the German Aviation Research Program, aims at closing the research gap for in-flight hardware tests on a retrofitted D328 using a combination of typical turboprop engines and Megawatt-scale hydrogen FC power with identical propulsion systems on each side. Due to safety aspects, this demonstrator aircraft is fitted with an additional propeller per side to house the electric motors driven by electric power from the FCs. This enables portions of the cruise to be flown hydrogen-electric only, thereby reducing emissions in the most climate-critical altitudes.
The presented retrofit study builds upon this concept but puts it into perspective for an assumed entry into service (EIS) in the year 2035 to enable an in-depth concept evaluation for a product rather than a demonstrator. The concept is based on the newer D328eco currently under development, as it features state-of-the-art engines capable of burning 100% sustainable aviation fuel (SAF) and has a longer fuselage designed for up to 40 passengers (PAX). The aim of these studies on a high-temperature FC and turboshaft engine dual-fuel parallel-hybrid concept is to develop aircraft sensitivities based on different propulsion system configurations to be able to derive powertrain requirements for future research and development activities. The selected approach features a dual-fuel parallel-hybrid propulsion system with one propeller on each side of the aircraft and turboshaft (TS) engines operating alongside hydrogen fuel cells. Rather conservative powertrain component assumptions were used to perform a realistic design space exploration for this regional CS25 turboprop aircraft retrofit. The lower bound for hybridization and technology options is estimated by studies on a minimum viable product with requirements on minimum range and PAX number. Nevertheless, these studies do not aim for a climate assessment or statements concerning hydrogen availability at relevant airports, as this is a purely aircraft-based analysis. Yet, they are part of the overall project scope.
1.1. Retrofit Concept
The Cambridge Dictionary defines a retrofit as “an occasion when a machine is provided with a part […] that the machine […] did not have when it was built” [
11]. Following this exact definition, the presented studies deal with the topic of conceptually equipping a D328eco regional turboprop aircraft with an alternative propulsion system without altering the structure of the baseline aircraft.
On the technical side, an aircraft retrofit comes with several challenges. As the aerodynamic surfaces (wings and empennage), as well as the fuselage’s external shape, may not be altered, the maximum takeoff mass (MTOM), as well as the center of gravity (CG), must stay constant. Slight changes in the CG are acceptable if the stability and maneuverability of the aircraft can be ensured. Nevertheless, CG changes will increase the trim drag of the aircraft and should, therefore, be kept at a minimum. The MTOM must not be exceeded as the structural margin for hard landings would be infringed upon or, generally speaking, the reengineering of specific parts would be required. The nacelles and propellers are allowed to be modified as long as the maximum wing-mounted mass is not exceeded. Otherwise, wing-root reinforcements would be necessary, leading to modifications in the fundamental structure of the aircraft and straying from the retrofit strategy.
For the study at hand, the choice of a retrofit allowed for a very good comparison of the performance characteristics of the hydrogen-hybrid powertrain compared to the conventional turboprop engines, as the underlying aircraft structure remained unchanged. No propulsion technologies with high modeling uncertainties were considered, e.g., distributed propulsion with its propeller-wing interaction.
A major challenge lies in the placement of the liquid-hydrogen tank due to its large volume and mass. Clean-sheet designs often assume a placement behind the aft pressure bulkhead to use the available space in the rear of the aircraft. This is especially tempting for the D328eco, as the rear part of the fuselage only contains the cargo area. Nevertheless, for a retrofit, this directly interferes with the CG requirements, if not counterbalanced. One option would be the placement of the fuel cells in the forward part of the aircraft as a counter mass. However, this introduces long, inefficient, and heavy power transmissions to the nacelles as well as large bending stresses on the fuselage. Moreover, the incorporation of an effective thermal management system poses a significant challenge, particularly when striving to maintain structural stability by avoiding the introduction of new openings for heat exchangers in the aircraft fuselage.
The chosen solution places the hydrogen tank in the cabin space close to the CG. This facilitates the aircraft design assessment but imposes challenges on the cabin design and safety. For further details, as well as possible solutions, see
Section 2.2.4. Lastly, this also implies that this retrofit concept only works with a reduction in passengers and thus payload, not only due to mass but also due to space restrictions imposed by the fixed fuselage dimensions.
1.2. Hybrid Powertrain Concept
The retrofit concept not only implies challenges and restrictions to the mass and CG location but also on the available options to integrate hydrogen fuel cells (FCs) into the powertrain of the aircraft. One of the most challenging parts of the integration of FCs into an aircraft is the thermal management system (TMS) with its heat exchangers (HEXs). The latter needs to be placed in the free stream of the ambient air, drastically reducing the available placement options of the FCs, if long coolant pipes or additional openings in the fuselage are to be disregarded. Even though an integration of the FCs inside the fuselage would be possible, the thermal effect on the structure, as well as the combined CG and drag variations, impose severe challenges on other aircraft design aspects. Especially, the LH2 tank—possibly the largest retrofitted mass depending on other powertrain component assumptions—should be placed close to the CG, allowing no room for FCs to be positioned at the same location without obstructing the passenger cabin entirely.
Therefore, the most promising solution was deemed by placing the LH
2 tank close to the CG inside the passenger cabin and the remaining systems within the nacelles located at the same wing position as the reference aircraft D328eco. For further details on the LH
2 tank and the propulsion system setup refer to
Section 2.
The chosen solution is a dual-fuel parallel-hybrid propulsion system with one propeller per aircraft side and TS engines working in parallel with hydrogen fuel cells. A schematic overview of the powertrain is depicted in
Figure 1 below.
The TS engine is located within the nacelle and is fed by fuel from the wing integral tank. Depending on the power fraction of the FC, the fuel quantity in the wing tank can easily be adjusted without modifications to the structure, as with conventional aircraft. The parallel use of the TS engine and FC allows the TS engine to be downscaled. For the study at hand, it is operated at 100% SAF.
The FC provides electrochemical power to the propeller via the power electronics (PE), the electric motor (EM), and the gearbox (GB). The latter is a two-shaft GB with entry shafts from the EM and the TS engine, combining their power to fulfill the propeller requirements. Hydrogen is fed through pipes from the LH2 tank to the FCs via the fuselage and wing, where it is converted to electric power using air (oxygen) from an aerospace-tailored compressor. The systems within the nacelle also include the TMS with its HEX providing the required cooling capability for the EM, PEs, and FCs.
Finally, a power cross-feed provides the required redundancy to direct electric power from one nacelle to the other in case of a major malfunction.
2. Aircraft Design Methodology
As the presented work is a purely theoretical study, modeling the conceptual aircraft within the Bauhaus Luftfahrt Aircraft Design Environment (BLADE) was a fundamental component of the study-related work. A detailed explanation of the overall BLADE aircraft design methodology and subsequent aircraft derivatives can be found in [
12]. BLADE primarily employs semi-empirical methods for aircraft sizing, focusing on mass estimation, aerodynamics, and overall aircraft performance [
12,
13,
14,
15], and is designed to interact with a CPACS (Common Parametric Aircraft Configuration Schema, [
16]) representation of the aircraft. Nevertheless, specific areas of interest are addressed using physics-based or analytical methods, including the assessment of the engine and fuel cell performance, as well as the hydrogen tank mass and thermodynamic calculations. All relevant assumptions and parameters need to be reflected within the model to allow the derivation of sensitivities for certain aspects of the design. This is especially relevant for the propulsion system, being therefore introduced in detail alongside its sizing logic and a general introduction to the hybridization strategies.
For the setup and calibration of the conceptual aircraft, a reference aircraft approach was used [
12]. This allowed us to derive a sophisticated model of the year 2035 retrofit. Finally, the overarching BLADE setup is introduced in the last section of this chapter.
2.1. Reference Aircraft
The previously introduced D328eco functions as the reference aircraft in the subsequent studies. Currently undergoing development by DA and originating from the Dornier Do 328, it serves as the focal point for investigation. The aircraft features a 3-seat abreast configuration with the aisle splitting it into a 1-seat and 2-seat side. Several modifications are being implemented in comparison to the D328. Besides introducing modern avionics and new landing gear, new powerplants are also being installed. The aircraft will be equipped with two PW127XT-S engines designed to be fully SAF compatible (for more details on the propulsion system, refer to
Section 2.2.1). Furthermore, comprehensive redesign efforts are being directed towards the fuselage and cabin. The fuselage of the D328eco represents an elongated iteration of the D328, featuring an augmented standard seating capacity accommodating up to 40 passengers. Visualizations of the D328eco can be found in
Figure 2 and further key specifications of the D328eco can be found in
Table 1.
This table also presents the top-level requirements for the aircraft (TLARs). While configuring the design mission, the payload mass was established at the equivalent mass of 40 PAX, aligning with an assumed seat load factor of 100%. The associated design range is extrapolated from a targeted payload-range capability provided by DA. It is imperative to underscore that the design mission, along with all ensuing studies, was calculated under ISA conditions.
2.2. Models & Methods
This section describes the models and methods for the conceptual aircraft design with their coupled assumptions for the major parts of the propulsion system. The TS engine still holds the largest power fraction provided to the propellers but is now supported by hydrogen FCs. The FC operation is adjusted independently for each flight point. A TMS and an LH2 tank are required to operate the FCs, forming the core of the dual-fuel hydrogen-hybrid powertrain concept together with the other components.
2.2.1. Turboshaft Engine, Gearbox & Propeller
For the presented studies, tabulated off-design engine-performance data for the PW127XT-S turboprop engine was derived from a generic turboshaft engine deck. It was split into a turboshaft deck and a propeller deck. Both decks were discretized based on rating, altitude, Mach number, and shaft power. The propeller deck incorporated thrust as an additional dimension, while the turboshaft deck included values for both fuel flow and exhaust thrust. Each deck contained more information, but only the aforementioned fields were extracted and utilized. This tabulated data was then interpolated for each flight point and the engine performance characteristics were determined and used in the mission calculation. To model the engine characteristics for different design points, the decks were scaled accordingly, based on a reference design point. The split into two decks also allowed for independent scaling between the propeller and turboshaft and thus enabled their use in a hybrid powertrain model, where the propeller might be powered by two or more independent power-delivery systems.
To define the powertrain design point, a total aircraft thrust was specified, and the propeller thrust, shaft power, and exhaust thrust were iterated to ensure that the combined propeller and exhaust thrust met the specified aircraft thrust requirement. The powertrain design point for the reference aircraft was chosen in a way that the originally provided data was preserved without any modifications, thereby ensuring the utilization of the reference engine’s performance characteristics.
Regarding mass calculations, the powertrain of the reference aircraft included a turboshaft, gearbox, subsystems, a nacelle structure, and a propeller. The mass of the turboshaft was computed following the methodology outlined in [
18], while the gearbox mass was determined using the approach detailed in [
19]. Both of these methods depended on the sea-level maximum shaft power that the turboshaft could provide. The gearbox mass also depended on the turboshaft and propeller shaft rotational speeds, which were derived based on [
20]. The nacelle structure and propeller masses, as well as the nacelle size, were modeled to vary with the powertrain design thrust and power. These regressions were calibrated to match the reference aircraft component masses and dimensions.
The subsystems are regarded to be powered by the turboshaft engine via an accessory gearbox. No power-offtake calculations were performed, as the additional fuel consumption and power increments related to the subsystems were accounted for in the turboshaft deck. The mass of these subsystems was assumed to be independent of the powertrain design point and therefore the reference aircraft subsystems mass was used for all aircraft variations. As this paper specifically focuses on a retrofit variant, examining the interdependency between powertrain size and subsystems falls outside the scope of the presented studies.
2.2.2. High-Temperature Polymer-Electrolyte Fuel Cell
For the presented study, the type of fuel cells was chosen according to a multitude of criteria derived from the aircraft’s operational requirements. The operational temperature, the power density, specific power, system efficiency, and response time during load changes were all taken into consideration, only to name a few. Based on these requirements, solid-oxide fuel cells (SOFCs) were disregarded, mainly due to their slow response time and delicate operational behavior as well as their air inlet requirements. Conventional polymer-electrolyte membrane fuel cells (PEFCs) have a good response time and show a good performance for the expected load cycle, but come with the drawback of a low temperature difference between its operating temperature, of around 80 °C, and the ambient air [
21,
22,
23]. As the aircraft design was only performed using ambient air to cool the systems, the use of high-temperature polymer-electrolyte fuel cells (HT-PEFCs) with an operating temperature of up to 220 °C was chosen. The higher temperature largely increased the temperature spread and, thus, alleviated the performance requirements of the thermal management system (TMS) due to increased thermal efficiency. Details of the TMS design can be found in
Section 2.2.3. The FC degradation effects were not considered [
24].
The FC model is based on the performance and hydrogen flow characteristics of the low-temperature 2017 Toyota Mirai FC [
25], adjusted towards the performance characteristics of an HT-PEFC operating at 220 °C. The FC system performance characteristics include all the balance of plant (BoP) system offtakes, apart from the compressor. Even though a lower BoP power consumption may be expected due to the water management being superfluous for an HT-PEFC, it remained unchanged.
To properly mimic the behavior of the reference FC characteristics, so-called virtual stacks were introduced. The virtual stack number was obtained by dividing the maximum power requirement of the FC system by the maximum power output of the reference FC stack. The virtual number of stacks could be a decimal number and was therefore amended by the term virtual, as it was purely a number used for correct system sizing and behavior representation. By following this approach, the correct scaling of non-linear stack parameters as the hydrogen flow or the system efficiency over power was ensured irrespective of the actual FC system power demand. These stack-dependent characteristics were derived from [
25], and amended by a specific FC idle rating to ensure a proper idle state for flight phases with low power requirements on the FC.
To account for the increasing compressor power consumption for higher altitudes, the maximum internal FC power was kept constant, but its power output to the propulsion system was reduced by the respective amount required by the compressor. This also ensured the correct FC hydrogen flow with respect to altitude and propeller power demand. The mass of the aerospace-tailored compressor, with respect to its maximum power consumption, was calculated according to a heuristic from [
26,
27], and its power consumption was assumed to be an increasing quadratic variation with altitude up to FL270 as shown in Equation (1)
according to a BHL-internal assessment.
It was refrained from using a buffer battery due to a multitude of reasons. Omitting a battery reduced the mass and system complexity, facilitated system behavior modeling, disabled quick turnarounds due to expectable charging times, and sharpened the focus of the studies on the TS-FC interaction. Certainly, it decreased the hybridization strategy options but therefore enabled us to draw a clearer picture of the expected drawbacks and benefits of this type of retrofit. Additionally, there was no mass reduction potential for batteries during cruise, which comes into play for longer missions. In particular, however, the dynamic behavior of FCs in the year 2035 was deemed sufficient to form a solid response time during power changes in conjunction with the TS engine, especially as the latter holds the larger power share and has its certified dynamic properties.
For this retrofit concept, the waste products of the FC system were not further utilized. The oxygen-depleted air, as well as the water vapor, are simply discharged via exhaust pipes into the ambient air, creating no additional thrust or drag. The vapor enhances contrail formation depending on the atmospheric conditions [
28], but as climate assessments were not part of these studies, no further insights were generated. Additionally, condensing liquid water out of the exhaust vapor was disregarded as this is a retrofit study, and it refrained from altering the structure and systems of the aircraft to accommodate this. The waste heat of the FC stacks was purely directed to the heat exchangers (HEXs), where it was discharged to the ambient air. Numerous utilization possibilities could be considered but were not the focus of these studies and were therefore neglected. Examples include nacelle and wing leading-edge anti-ice systems, environmental control system (ECS) heating, or hydrogen system component heating.
2.2.3. Thermal Management System
Given its substantial impact on the overall performance of the hybrid-electric powertrain, considerable attention was dedicated to the examination of the thermal management system in this study. At BHL, the in-house developed, python-based fluid simulation environment ICCE (Innovative Cooling Concept Environment, [
29]) is being used to perform all relevant TMS calculations. It incorporates fluid and fin databases, and a core library defines the microscopic geometry of the heat exchanger surface on the hot and cold sides. As a modular thermodynamic cycle program, it provides the ability to combine various TMS-specific components into the desired cooling system setup, making it adjustable to numerous aircraft-specific cooling problems. The components include, but are not limited to, pumps, pipes, nozzles, diffusers, fans, cooling liquids, and heat exchangers (HEXs). They are sized using a multipoint design strategy for hot-and-high takeoff (high density altitude) at the desired deviation from the international standard atmosphere (∆ISA) as well as cruise conditions. The ∆ISA was set to +25 K for this retrofit application case.
Independent investigations were performed before the actual powertrain sensitivity studies, as ICCE was not directly coupled to BLADE but needed to be executed in advance. A fixed TMS configuration was derived and was not altered throughout the aircraft design process. The results of the aforementioned studies were then integrated into BLADE by means of general performance parameters, such as specific power or power density. After the first estimations on the expected waste heat of the hydrogen-electric system were obtained, the TMS was designed and calculated for a range of input parameters to derive the overall system behavior trends. A multipoint design for takeoff ambient conditions at ∆ISA = +25 K, as well as designed cruise conditions, was carried out to ensure the correct sizing of the TMS for all expected conditions. The system was then optimized in terms of mass, drag, and power consumption according to reference (turboprop) aircraft sensitivities for an intermediate-to-high power fraction provided by the FC (e.g., 20%), resulting in waste-heat values of around Q = 350 kW to be handled by the TMS. For lower power fractions resulting in heat loads deviating from this optimization target, the error of the TMS calculation increased, but became smaller in absolute values, as the overall heat load was reduced. Therefore, this approach was deemed sufficiently accurate for the planned studies.
Furthermore, the heat rejection capability of the FC was varied between 20 K and 40 K by altering the inflow and outflow conditions of the FC coolant with respect to its operating temperature of 220 °C. This enabled the analysis of the effects on the HEX drag due to the energy (waste heat) injected into the airflow.
The final TMS architecture consisted of a diffusor leading to a compact ram air HEX. Succeeding the HEX, a nozzle tried to convert the injected heat energy into thrust (reduced drag). For hot day ground operations, a puller fan was installed in the flow direction behind the HEX, which in turn was provided with the waste heat by a pumped cooling liquid. Within the BLADE calculations, the TMS was sized according to two input variables: the waste heat of the FC and the waste heat of the electric components (PEs & EM) at each given mission point. The electric component of waste heat was derived by the power throughput and the efficiencies of the components under the assumption that all losses are converted into heat, which can be discharged by the TMS (no radiation or convective cooling within the nacelle). The waste heat of the FC, derived from its efficiency-over-power characteristic at each mission point, was then added to the electric component of waste heat and formed the sizing requirement for the TMS. Note, that the power consumption of the TMS was dependent on the amount of waste heat to be discharged, which iteratively increased the power requirement of the FC. To control this, an additional parameter was introduced, referred to as the TMS power ratio, which is defined as the power required to operate the TMS as a fraction of the waste heat it has to handle.
The higher operating temperature of the HT-PEFC led to high TMS specific powers, thus leading to a smaller system size which could be integrated directly into the nacelle. This led to two independent cooling systems: one for each nacelle’s FC system with each having one HEX on the side of the nacelle generating additional drag due to the nacelle surface-area increase and the HEX pressure loss. There were no additional wires or pipes required from outside of the nacelle, as the TMS power consumption was entirely covered by the FC.
Advanced technologies such as the pre-cooling of propulsion system components with the cryogenic hydrogen during refueling or using the hydrogen on board as a heat sink were neglected as the focus of the study was on a short-term technology level. A summary of the incorporated TMS design parameters with their respective values can be found in
Table 2 in
Section 2.2.5.
2.2.4. Liquid Hydrogen Tank & System
Compared to gaseous hydrogen, liquid hydrogen (LH
2) has a higher volumetric and gravimetric energy density and was therefore chosen as a storage state for the hydrogen required to fuel the HT-PEFCs. The cryogenic temperatures required to store the LH
2 come with several challenges such as a high power demand for the liquefaction before fueling the aircraft or comparably heavy tank systems. Nevertheless, the drawbacks of alternative storage methods are seen as less performant on aircraft level and are thus disregarded. Even though foam-insulated cryogenic tanks are cheaper and lighter, a vacuum tank design was chosen for its low thermal conductivity, and thus its boil-off rate [
30].
The LH
2 tank was designed directly within the aircraft design loop of BLADE with the in-house developed OpenMDAO-based tool HyDRA (Hydrogen tank Design, Ramifications and Assessment, [
30]). This tool considers various parameters such as the allowable boil-off rate, ambient conditions, venting pressure, material properties, and safety factors and sizes the tank according to the required LH
2 storage mass. Given the geometric constraints, a thermal design of the insulation layer. as well as the mechanical design of the structural layer, were performed following a simplified approach [
31,
32].
The LH2 tank was set up to have a constant outer diameter of 1.08 m between the end caps, as this was the maximum possible diameter that could be fitted at the 2-seat side of the cabin without interfering with the aisle space. The end caps formed round semi-spheres and thus had a length of 0.54 m each. The maximum allowable length for the entire tank was 3.81 m due to the maximum allowable number of seats to be removed (five rows).
Even though HyDRA may calculate and place multiple tanks simultaneously, it was decided to only include one single LH
2 tank, as the low power contribution of the FCs required no redundancy. Moreover, the tank was designed only for the design mission, as the diversion was planned to be flown by the combustion engines only (for more details refer to
Section 2.4). Furthermore, the available space imposed a major challenge; for two tanks, two more end caps would decrease the maximum volume available for hydrogen storage.
As one of the main challenges during the conceptualization of a retrofit is to keep the center of gravity (CG) within its former certified bounds, the only feasible option for the placement of the LH
2 tank lies within the central fuselage section close to the wings. A placement in the aft fuselage would shift the CG too far aft, even though the cargo compartment of the D328eco would be well suited for such an integration. Placing it into the central fuselage section is in direct conflict with the passenger cabin and leads to the compromise of placing it at the two-seat side of the cabin, contained in a separate fairing due to safety reasons. This placement blocked no emergency exits, as depicted in
Figure 3, but required the removal of passenger (PAX) seats according to the required LH
2 mass and, thus, the tank size. Furthermore, this compromise allowed the tank to be placed close to the MTOM’s CG, as this was imperative for retrofit studies.
The hydrogen is transferred to the FCs via a vacuum-insulated piping system [
33], which is calculated to start at the bottom of the tank, follows the curvature of the fuselage until it reaches the wing root and then splits into two pipes—one for each nacelle. A total pipe length of 14.85 m was calculated for the entire aircraft, including the nacelle internal routing. As the hydrogen flow rate required by the FCs under full load was comparably low due to the overall small power fraction on aircraft level, the piping was assumed to be for gaseous H
2 only. This led to the assumption that no additional power consumption was required to heat the H
2 within the pipes before entering the FCs, but around 15 kg of insulation mass for the protection of the aircraft structure against the cool pipes was added [
34]. With an assumed mass of 2.0 kg/m for the filled tube and 5 kg of system installation mass, the entire mass for the H
2 transfer system was approximated to be around 50 kg. The LH
2 tank was placed inside a compartment to shield the cabin from any potential hazards related to it and its operation (refilling, leakages, etc.). Potentially, the ECS could provide a separate heating inflow into the LH
2 tank compartment to avoid the accumulation of excessive cool air, as well as condensation moisture.
Additionally, the venting would remove potential hydrogen accumulation and discharge it via a specific exhaust located at the top aft corner of the LH
2 tank compartment, thus, exiting the aircraft behind the wings trailing edge through the fuselage. Venting through the vertical tail plane (VTP) for maximum height above ground, as typically seen in clean-sheet designs, was disregarded as an installation through the existing structure was deemed not feasible for a retrofit and would shift the focus of the studies away from the powertrain configuration options. As the H
2 quantities are comparably low, the chosen approach was considered to be adequately safe. The LH
2 tank compartment also serves as a barrier for the passengers in case of a major tank malfunction or tank rupture, with the same vent opening acting as pressure relief valves towards ambient conditions. This is especially important, as larger tanks approach the blade-off hazard angle of the propeller (±15° from the propeller plane, [
35], see
Figure 3). The mass of the LH
2 tank compartment walls was not taken into account, as it may be weighed against the removal of other furnishing parts as wall panels or window blinds. Nevertheless, it should be stated that the safety management for a cabin tank is far more critical than for an aft fuselage tank and would need further investigation.
2.2.5. Hybrid Powertrain Components
Due to changes in the powertrain, the nacelle volume needs to account for numerous additional systems. The nacelle surface was sized according to the actual volume of the incorporated systems with an additional oversizing factor of 5% to account for the reduced packaging efficiency of components.
For redundancy purposes, between the nacelles, there was a power cross-feed installed. This cross-feed enabled the transfer of electric power from one nacelle to the other in case of an FC system malfunction. The mass was assumed to be 5 kg/m, including all relevant safety switches and accessories. With a total cable length of 10.1 m, including 1.5 m routing within each nacelle, the entire mass of the power cross-feed was 50.55 kg.
The DCDC converter and DCAC inverter were resolved as two separate components within the powertrain assessment during the aircraft design loops but are referred to as power electronics (PEs) to simplify statements. They convert the power coming from the FC system to voltage levels and frequencies usable by the electric motor (EM). The incorporation of performance maps for these electric components was not deemed beneficial for the chosen model setup and did not align with the overall level of detail employed in other aspects of the design loop; hence, it was disregarded. This is valid assuming, that there were no significant EM efficiency changes between the design and off-design. Moreover, the negligible transmission distances between the respective components within the nacelle strongly reduce the impact of voltage-coupled performance maps. Therefore, the mentioned electric components were modeled based on specific power, efficiency, and power density without the assumption of large technological advancements for an EIS in 2035. Details can be found in
Table 2 below.
A three-shaft gearbox is considered for this propulsion system, having one shaft for the turboshaft engine and one for the electric motor. The power of the two shafts is then combined and fed to the propeller. This concept allows for two different entry-shaft speeds, thus enabling each system to operate at its optimum. Furthermore, the separation enhances redundancy compared to an electric motor placed directly on the power shaft of the turboshaft engine. As this gearbox design differs from conventional configurations, the calculated GB mass was scaled by a factor of 1.2 and it then depended on the combined sea-level maximum power of the turboshaft and electric motor. The GB was expected to be air-cooled with no additional power consumption to be considered.
Between the EM and GB, as well as the TS and GB, shaft and bearing mechanical losses were considered as these were required for proper load bearing and vibration damping. A summary of the most important parameters is showcased in
Table 2.
Table 2.
Hybrid propulsion system component assumptions.
Table 2.
Hybrid propulsion system component assumptions.
High-Temperature Polymer-Electrolyte FC | Value | Unit |
---|
Max. stack power | 114 | kW |
Idle power | 4.7 | kW |
Max. system efficiency | 0.637 | - |
Power density | 4.2 | kW/L |
Specific power | 1.5 | kW/kg |
Operating temperature | 493.15 | K |
Thermal management system | | |
Specific power 1 | 5.0 | kW(heat)/kg |
Power density 1 | 2.0 | kW(heat)/L |
Power ratio | 0.08 | - |
Mechanical components | | |
Mechanical transmission efficiency | 0.995 | - |
Gearbox transmission efficiency | 0.985 | - |
Gearbox power density | 80 | kW/L |
Gearbox mass factor | 1.2 | - |
Electric components 2 | | |
Cable mass | 5.0 | kg/m |
Power electronics efficiency | 0.991 | - |
Power electronics specific power | 15.6 | kW/kg |
Power electronics power density | 20.4 | kW/L |
Electric motor efficiency | 0.978 | - |
Electric motor specific power | 19.1 | kW/kg |
Electric motor power density | 35.1 | kW/L |
2.3. Study Setup
In this section, an elucidation of the study’s setup is presented. The objective of this study is the conceptual design of a hydrogen-hybrid aircraft retrofit. In facilitating the comparative analysis and discussion regarding potential advantages conferred by innovative technologies, it is essential to incorporate both a reference aircraft as well as an EIS 2035 baseline aircraft. Given the adoption of a retrofit methodology, the assumption was made that no prospective advancements were applied to the aircraft aside from the integration of the novel propulsion system. Consequently, considerations pertaining to aerodynamic or structural innovations were excluded and there were no modifications to the subsystem, as these are already included in the engine deck in the form of fuel consumption (details see
Section 2.2.1). Therefore, the contemplation of an EIS 2035 baseline aircraft became negligible, and only the reference aircraft was taken into account for comparisons to derivatives of the future hydrogen-hybrid aircraft retrofit in the ensuing studies.
In the course of these studies, aircraft modeling was conducted in the BLADE framework, which was introduced at the beginning of this chapter. More information on the sizing process can be found in [
12]. The first step of the setup involved the meticulous calibration of the reference aircraft. To achieve this, all relevant data encompassing geometric attributes, mass distributions, and CG locations were derived in close cooperation with DA. Employing this dataset as the input, the aerodynamics of the aircraft model underwent calibration to ensure congruence with a predefined payload range diagram, thereby aligning the resulting mission performance data with the specified criteria.
The next step in the study setup involved the conversion of the calibrated reference aircraft into a hydrogen-hybrid configuration. Given that the hybridization is executed as a retrofit, the geometric and mass characteristics remained invariant, with alterations permitted exclusively with respect to the propulsion system. The sizing of the propulsion system was orchestrated within the iterative aircraft design loop. This iterative process entailed the adjustment of the design top of climb (TOC) thrust to meet the stringent criteria of both takeoff field length (TOFL) and time to climb (TTC). The sizing of the powertrain was contingent upon the most restrictive criterion among them, which was dynamic and could change throughout successive iterations of the sizing process.
As the turboprop engines of the reference aircraft are capable of using pure SAF alongside conventional Jet A-1 kerosene, the retrofit studies aimed for the best-case scenario of burning pure SAF. To enhance data transparency, SAF from 100% hydrotreated esters and fatty acids (HEFA) was used instead of a more typical blend. Both fuels have a value range for density and lower heating value (LHV), but it was decided to proceed with the following values according to [
38]: a density of 757.0 kg/m
3 (Jet A-1: 790–810 kg/m
3) and an LHV of 44.1 MJ/kg (Jet A-1: 43.2–43.3 MJ/kg). The increased fuel volume due to the reduced density of the SAF had no impact on the retrofit design and the use of the wing integral tanks, as the fuel required, was decreased depending on the power fraction of the FC.
As the aircraft embodied a dual-fuel hybrid configuration, it became imperative to account for the changes in fuel mass and the LH
2 tank. Commencing with a computed SAF mass for the reference aircraft, the requisite SAF and LH
2 masses were derived through the utilization of their LHVs and a predefined power split, expanded in the following
Section 2.4. This facilitated suitable initial conditions for the aircraft design process and mitigated the risk of divergence. Subsequently, during each aircraft iteration, the SAF and LH
2 masses were computed utilizing the engine deck and fuel cell model, respectively, based on the mission performance data, and the LH
2 tank dimensions and mass were calculated using HyDRA.
As the incorporation of supplementary propulsion system components inevitably leads to a higher total propulsion system mass while the MTOM must remain invariant, a reduction in payload mass was necessitated in exchange. The requisite reduction of payload mass was dynamically incremented to offset the augmented mass contributions emanating from the propulsion system, tanks, and fuels, ensuring an alignment with the prescribed MTOM.
Given the stipulated minimum requirements for the retrofit to still result in a reasonable product, a further constraint pertaining to the dimensions and placement of the LH2 tank was introduced. Since the tank was positioned inside the fuselage, the payload had to be removed. The tank width was predetermined according to cabin constraints while the length was adjusted to match the required volume with the necessary LH2 mass. The tank’s length exerted influence on the passenger count, which was adjusted according to the remaining available seats. In compliance with the requirement of a minimum capacity of at least 30 PAX, an upper limit on the maximum tank’s length was imposed. It is imperative to emphasize that the payload constituted a composite of passengers and cargo. Consequently, its reduction was not executed discretely through the removal of a specific count of passengers but changed continuously on a per-kilogram basis, adhering to the constraints imposed by the maximum tank length.
The sizing of the propulsion system and masses were iterated during the aircraft design loop until all values were converged and the sizing goals were met.
2.4. Hybridization Strategy
Considering the hybrid powertrain described in
Section 1.2, and the sizing process outlined in
Section 2.3, an additional parameter needed to be specified to control the power allocation between the TS and the FC. This parameter is referred to as the power split (S
P) and is defined in Equation (2):
with
as well as
and
with the PE efficiency being counted twice to account for both the converter and inverter. Consequently, a power split definition was required for the design point and each mission flight point.
In this study, each aircraft mission was modeled as a collection of segments, each having different specifications regarding the powertrain operation. Throughout any cruise and loiter segments, the powertrain was configured to meet the aircraft’s thrust requirement, thus a power split needed to be defined. However, during any takeoff and climb segments, the powertrain was engaged at its maximum available power, and during any descent and landing segments, it operated at idle. Therefore, no power split specification was required. This led to a variable power split during these segments, dependent on the power lapse of each system with altitude due to the decrease in air density. Based on the models detailed in
Section 2.2.1 and
Section 2.2.2, the FC power lapse was less significant than that of the TS, leading to an increased power split with altitude.
Moreover, the incorporation of FCs yielded emission reductions mainly during the cruise, leading to the deliberate exclusion of FC operation during the diversion. This strategic decision was reinforced by the potential consequence of increased hydrogen usage, which could lead to tank lengths exceeding the predefined limits.
An additional strategy was considered, for which the fuel cell was operated at its maximum power and the turboshaft was de-rated to match a prescribed power split for all segments. Since the takeoff and climb segments were used for the powertrain sizing, see
Section 2.3, this de-rating would result in an oversizing of the turboshaft and its available power would not be fully utilized. For this reason, such a strategy was not further explored.
4. Discussion
Given the target to minimize development time and risks, as well as infrastructure changes, retrofitting existing aircraft, such as the D328eco used in the presented study, might be a valid option. It can be concluded that for a carefully selected set of assumptions, a dual-fuel hydrogen-hybrid retrofit of the D328eco aircraft is feasible. Even though a reduction in the passenger number is inevitable, an integration of hydrogen FCs will reduce emissions, especially in the most climate-relevant section of the flight—the cruise.
The hybrid baseline with its power split of 0.2 led to a SAF reduction of 12.9% while the payload was reduced by 18.1% to counteract the increase in propulsion system mass and the addition of the LH2 tank mass. Moreover, changes in the CG location, due to the placement of propulsion system components, decreased the lift-to-drag ratio by 0.5% due to an increase in trim drag.
These two effects summarize the challenges of retrofit designs well; the limited component-placement flexibility of the propulsion system due to the enlarged system and the aircraft modification restrictions induce negative properties in terms of CG location and mass. Apart from a series of requirements, it must especially be ensured that the wing-mounted mass is not exceeded, since for this type of retrofit the propulsion system mass is the focal point.
Specific power variations revealed that the TMS has a greater lever in terms of mass compared to the FC system. The mass increase resulting from halving the FC specific power was 68.4% of the mass increase arising from the halving of the TMS specific power. Additionally, the lower power density of the TMS compared to the FC resulted in raised drag values, thus leading to higher thrust requirements and in turn a larger and heavier propulsion system.
Independent FC oversizing reduced hydrogen consumption by 7.7% with no significant effects on SAF, even though the increase in propulsion system mass needed to be counterbalanced by a decrease in payload mass. This underlines that oversizing is generally beneficial for longer flight distances, as the hydrogen mass savings due to the efficiency increase during cruise might outweigh the FC system mass increase. In case a maximum SAF reduction is aimed for, the oversizing allows for higher cruise power splits. For a FC oversizing of 40%, the power split could be increased to 0.28 (baseline: 0.2), resulting in a 32.4% increase in hydrogen required with a simultaneous reduction in SAF by 3.6%. Based on these results, FC oversizing and cruise power split maximizing was found to be the most successful approach investigated to minimize total SAF mass and, therefore, emissions. However, to minimize SAF per passenger, used as an alternative metric for comparison against the reference aircraft, no oversizing is deemed beneficial.
The studies were completed by investigating the lower limit of the powertrain assumptions to derive a minimum viable product incorporating a low-temperature PEFC and coupled low-performance assumptions. For a set of minimum requirements, the MVP achieved a reduction of 63.8% of SAF consumed per PAX compared to the hybrid baseline, while maximizing the power split, reaching a value of 0.298. Based on these results, the development potential of a D328eco retrofit could be judged while keeping the HT-PEFC studies in mind.
A key enabler for the presented retrofit is the FC design choice in conjunction with the TMS. Due to the large share of the mission requiring constant FC power, an aerospace-tailored FC design should differ from automotive applications in contrast to the chosen reference FC to maximize performance. Particularly, as high temperatures greatly enhance overall system performance, specific HT-PEFC designs should become the focal point of future developments. It may be expected that an aerospace-specific FC design might lead to more favorable characteristics, as costs are less relevant than in the automotive sector and different requirements are put into place (load characteristics, cycle number, system size, and mass, drastic changes of ambient conditions, etc.). Progress was claimed in this regard [
39], but needs to be verified in actual applications.
The combination of the compressor with the environmental control system (ECS) would most probably be possible, as the ECS unit of a D328eco is in the frontal wing root above the cabin and additional space could be allocated. Furthermore, this would place it between the nacelles and allow for a simpler distribution of the compressed air. The drawbacks arising from this modification include the deterioration of redundancy, the additional piping length requirements, and the increased system cost due to complexity.
The TMS setup is directly coupled with the FC system performance. Depending on the requirements placed on the TMS design it may have a large lever on the overall aircraft performance as outlined in
Section 3.1.2. Therefore, more advanced systems or altered operational strategies, compared to the typical compact HEX used for the presented studies, could yield superior TMS performance. An example of an alternative operational strategy could be the use of the FC on cruise only, strongly increasing the lowest temperature spread due to the low ambient temperatures during the cruise. Yet, this comes with strong changes in the overall operational concept and would prevent emission-free airport operations on FC power only. Note that the TS engine would be required to still be operated, though at idle, to enable sufficient warm-up time. Furthermore, the propeller slipstream was not taken into account for the TMS design, underlining the rather conservative TMS design approach.
The heat rejection capability of the FC was found to have a major impact on the TMS performance. Therefore, it is a fundamental aspect to be considered for future aerospace-tailored FC designs. This is closely coupled to the properties and flow velocity of the cooling liquid chosen. Using the LH2 as a heat sink, or to pre-cool e.g., electric systems, could be an option but was dismissed due to the model setup and uncertainties regarding technological readiness. A single TMS serving both nacelles could potentially be coupled with the ECS but would make a true retrofit less feasible, as more system changes to the baseline aircraft would be required.
As the LH2 tank size is never limiting according to the assumptions chosen for the presented studies, the redundancy and hazard impact could be improved by incorporating two separate tanks, even though this comes with a mass penalty. This, in turn, prompts the question of whether identical or varying sizes and, consequently, mass distributions should be considered. In addition, the presence of multiple tanks also allows for various de-fueling strategies which can be tailored to optimize the CG shift during operation. Tank configurations with total lengths that result in maximizing the space utilization arising from seat row removal should be preferred, as these should lead to higher removed payload to LH2 mass ratios. Furthermore, sloshing could be an additional consideration for longer tanks giving rise to a new set of aspects that should be investigated; however, this was not investigated with the current model setup.
On overall aircraft level, further modifications that were not part of the presented studies could be considered while keeping the retrofit requirements in place. If mass savings can be expected, specific subsystems could be electrified or interactions could be considered, such as using parts of the waste heat for wing anti-icing. Nevertheless, during the conceptualization of a retrofit, the overall costs play a major role and may outweigh investments in too complicated/expensive modifications, differentiating a retrofit, to a certain degree, from clean-sheet designs.
Finally, the aircraft size selected for a retrofit is of considerable importance, as trades between the cost of the modifications, design range of the retrofit, and propulsion system mass fraction vary massively between the different aircraft types. Regional aircraft may act as an enabler for the first hydrogen-hybrid retrofit concepts, as they commonly operate on less congested routes in remote regions, where there are few transport alternatives (e.g., Scandinavia, Canary Islands, etc.), but no long distances need to be covered. These shorter-range missions require lower total energy carrier quantities on board and have a reduced payload demand, rendering them ideal candidates for the integration of presently less power-dense propulsion systems.
It should be noted that retrofit considerations are a function of a multitude of requirements, with economic considerations commonly prevailing. The planned type of operation and especially the availability of hydrogen at relevant airports, including the refueling infrastructure, are of utmost importance for the realization of the discussed concepts and should therefore always be analyzed in parallel.
5. Conclusions
Various sensitivity studies were carried out on a dual-fuel hydrogen-hybrid regional aircraft retrofit based on the D328eco featuring a parallel-hybrid powertrain incorporating TS engines and HT-PEFCs as well as an LH2 tank located inside the passenger cabin.
The hybrid baseline with its power split of 0.2 led to a SAF reduction of 12.9% while the payload was reduced by 18.1% to counteract the increase in propulsion system mass and the addition of the LH2 tank mass. Specific power variations of FC and TMS revealed that the TMS has a greater lever in terms of mass. Additionally, the lower power density of the TMS compared to the FC resulted in raised drag values, thus leading to higher thrust requirements and in turn a larger and heavier propulsion system. Independent FC oversizing reduced hydrogen consumption by 7.7% with no significant effects on SAF, even though the increase in propulsion system mass needed to be counterbalanced by a decrease in payload mass.
The studies were concluded by investigating the conservative, lower limit of the powertrain assumptions to derive a minimum viable product incorporating a low-temperature PEFC. For a minimum of 200 NM (baseline: 580 NM) and 30 PAX, the MVP achieved a reduction to 63.8% of SAF consumed per PAX compared to the baseline while maximizing the power split to 0.298. Nevertheless, on the other hand, this came with a significant 85% increase in SAF mass per PAX per NM.
As this article focuses on the setup of the reference and retrofit aircraft, as well as on the sensitivity studies for a range of powertrain parameters, a deeper analysis of the limiting cases and a refinement of the studies remain open. Future work should consider operating the FC during diversion since this might lead to enhancements in the TS-FC combined performance and possibly allow for higher achievable power splits. In direct dependency to the diversion is the use of two LH2 tanks for redundancy. Moreover, for a given design, the typical mission should be analyzed to gain an understanding of the in-service performance of the retrofit, enabling an independent segment-wise power allocation optimization. Finally, to compare the reference aircraft against its hybrid evolution from an emissions standpoint, the typical mission aircraft characteristics have to be derived and paired with a corresponding fleet model, such that the overall environmental impact is appropriately considered.