3.1.1. Reference Design Range: 600 nm
The impact of battery technology maturity on overall hybrid–electric aircraft feasibility has been assessed by means of a
BED sensitivity analysis, varied in the (200, 500) Wh/kg interval [
38], considering the complete battery pack. Note that in this range, the lower value is close to the state of the art [
39,
40,
41], whereas the upper value represents a consolidated forecast for 2035 [
42,
43]. The reference full–thermal regional aircraft, designed with the same procedure and by enforcing the condition
= 0, exhibits MTOW = 15,780 kg,
= 1103 kg, and
PREE = 0.869, while
Table 1 shows the data for
-optimised configurations as a function of the
BED value in the selected range.
These numerical results highlight two key aspects: (i) Given the state of the art of batteries (but also for incremental technology steps up to 100% with respect to the current achievable value of the
BED), no significant benefits can be expected from the utilisation of electric power as the weight increases related to the batteries are overwhelming, so the optimal solutions show low in-flight electric power supply; (ii) With an entry-into-service horizon of 2035, the use of hybrid–electric powertrains can contribute to substantial reductions in
, but sharp increases in MTOW must be taken into account. Indeed, for the reference
BED = 500 Wh/kg, the advantage in the implementation and utilisation of electrical power, which can be observed from the values of
and
, respectively (see
Table 1), results in reductions in
but at the expense of a significant increase in MTOW. On the other hand, for lower values of the
BED, the search for power electrification does not introduce a tangible benefit. To better highlight these trends, the optimisations previously described have been carried out by introducing the constraint MTOW =
, with
varied in the (15, 50)
10
3 kg
f interval. In this context,
Figure 2 shows the trend of the optimal
obtained as a function of the value of
.
From a technical standpoint, increasing the value of allows for an increase of the amount of the on-board battery power, hence allowing for the growth of the in-flight electrical power utilisation. The simulations results show a worsening trend in terms of as increases for values of the BED equal to 200 and 300 Wh/kg, bringing to light the fact that with these levels of battery technology, the penalties resulting from the weight increases due to the batteries are definitely greater than the benefits of using a share of electrical power to satisfy the energy required for the flight. For a value of the BED equal to 400 Wh/kg, the beneficial and detrimental effects seem to offset each other, resulting in no noticeable benefit in terms of as the possible number of batteries on board increases. The trend is inverted for a BED of 500 Wh/kg because the larger the number of batteries on board (hence the possibility of supplying electrical energy in flight), the higher the benefit in terms of reduction.
In other terms, the level of technological maturity of batteries defines the actual feasibility of regional hybrid–electric aircraft, if benefits in terms of
are the performance index. In fact, as shown in
Figure 3, although increasing
allows for similar on-board battery mass increases for all the values of
BED considered, only the technological value predicted for 2035 provides significant fuel consumption reductions.
The trend between
and MTOW thus points to an observation regarding the energy efficiency of the hybrid–electric aircraft. In fact, for these optimised configurations, increases in MTOW correspond to reductions in
PREE for all the
BED values up to the forecasted reference for the 2035, as shown in
Figure 4.
To discuss this contrast between metrics related to emissions (
) and those related to aircraft operating efficiency (
PREE), a second set of optimisations in which the
FoM to be maximized was set equal to the
PREE was performed. In this context,
Table 2 shows the obtained results.
Even for the
PREE, if we consider the state of the art of the
BED, the optimal results tend towards configuration with a low in-flight electric power supply, and a similar trend is found for a value of the
BED equal to 300 Wh/kg. For these configurations, in fact, maximizing the lift-to-drag ratio (hence maximizing the
W/
S) and minimizing the take-off weight coincides with minimizing the energy required for flight
E and, therefore, since the payload and range are fixed, with maximizing the
PREE. The situation slightly varies for
BED = 500 Wh/kg, for which the
PREE-optimal configuration substantially differs from the
-optimal one. In fact, while exhibiting a non-negligible share of electrical power utilisation, the
PREE optimum is far from that relevant to
and settles around much lower MTOW values. Once again, it is evident that for hybrid–electric aircraft, conflicts occur that differentiate sizing in the case of seeking solutions oriented towards reducing the fuel consumption (environmental benefits) or increasing the energy-efficiency metrics (operational benefits). To validate this hypothesis, also for the
PREE optimisations, several runs were performed with the MTOW
= constraint, whose results are shown in
Figure 5. In particular, for a value of the
BED up to 300 Wh/kg, increasing
leads to penalisations in
PREE, as the main contribution in increasing MTOW results in higher energy required to perform the mission. A slightly different trend is evident for
BED values equal to 400 and 500 Wh/kg, where the maximum is obtained at
larger than the minimum values.
This occurs because there is a trade-off between the two different contributions to the energy required for flight because increasing
results in a larger energy demand to trim the aircraft in flight, while on the other hand, it allows for an increase in the on-board battery mass and thus in a higher share of electric power supply. This aspect, for a parallel hybrid–electric powertrain, increases the total propulsive efficiency
defined as
where 𝜆 is the ratio between the power supplied by the battery and the total supplied power [
44]; while
,
, and
are the efficiencies of the thermal engine, electric motor, and gearbox, respectively. In particular, as discussed in [
8], increases in 𝜆 (associated with increases in MTOW) imply increments of
, as shown in
Figure 6 on the left. This propulsive efficiency effect is, however, of minor significance on the overall requested flight energy for a value of the
BED up to 300 Wh/kg, while it has a beneficial prevalence with respect to the increase in aircraft weight up to 22,000 kg
f for the case with a value of the
BED of 500 Wh/kg, where (slight) reductions of
E can be observed (see the right part of
Figure 6).
Figure 7 shows the results in terms of
for the
PREE-optimised configurations, in which a similar trend (with respect to MTOW) to that obtained for the
-optimised configurations (see
Figure 2) is observed.
Setting PREE as FoM, hence, may lead to a better utilisation of on-board power sources, providing energy-efficient aircraft operations. However, this conduces to solutions that are close to the thermal-powered aircraft if the current technology for batteries is considered and to a slightly lower-power hybridisation if the technology for 2035 is considered. This aspect does not lead to actual savings in terms of fuel consumption and hence is not an effective strategy to cut greenhouse gas emissions from regional aircraft operations. Indeed, the results here discussed highlight that a paradigm change in conceiving and developing regional hybrid–electric aircraft is necessary to reach the environmental targets for which this technology is under investigation. In fact, with current technology forecasts for 2035, it seems that accepting having a much higher MTOW (and hence energy consumption) than that of the state-of-the-art full-thermal aircraft turns out to be a necessary price to pay if actual emissions benefits are to be achieved. That conclusion is true if we consider only flight-related emissions. Indeed, even in the 2035 technological scenario, the higher energy quota necessary to cut fuel consumption, compatibly replaced by electric energy stored in the batteries, should come from renewable sources if an overall environmental benefit is to be attained.
3.1.2. Effect of Varying Design Range
This section describes the effect that design range variations have on the design and performance of regional hybrid–electric aircraft. First, the optimisations described in the previous section were replicated by reducing the design range to 400 nm. That value is representative of many typical missions in the regional market, as documented in [
24]. We first present the results for the optimisations in which the
FoM is set equal to the block fuel; then, different sets of optimisations were carried out again to vary the MTOW
= constraint. In
Table 3, the results related to the optima–
configurations with a design range of 400 nm are reported.
The comparison with the corresponding results obtained for the reference range (namely, 600 nm, see
Table 1 and
Figure 2) reveals some substantial differences. First, since the energy demand to perform a shorter mission is lower, it is trivial to obtain general reductions in fuel consumption, which is obviously also true for full-thermal configuration. Note that for the full-thermal benchmark, MTOW = 15210 kg
f,
= 734 kg, and
PREE = 0.871 are obtained. The differences are thus mainly to be found in the effect of the
BED and MTOW variations. In fact, it can be observed that as MTOW increases, even substantial reductions in
can be obtained for
BED = 400 Wh/kg (see the left part of
Figure 8), a circumstance that did not occur at a range of 600 nm; slight reductions as MTOW changes are also visible for
BED = 300 Wh/kg, which are in any case slight, but considerably better than the results relating to the state of the art in battery technology.
In particular, as MTOW increases, sharp reductions in
are obtained, both for
BED 400 and 500 Wh/kg so that, with respect to the thermal benchmark, reductions of 88% (with an increase in MTOW of 210%) are obtained for
BED = 400 Wh/kg, and even reductions of 97% (with an increase in MTOW of 146%) are achieved for the
BED = 500 Wh/kg case. In this scenario, there is a
= 10 kg, i.e., only the take-off share, while the standard airborne mission is fully accomplished with only electrical power. Regarding the values of
PREE obtained for the
-optimised configurations (see the right part of
Figure 8), the numerical results show that in case of BED = 500 Wh/kg, the value of the
PREE increases until it reaches a maximum of 1.3 for an MTOW near 32,000 kg
f, then the trend is reversed and
PREE decreases. In this case, a more beneficial trade-off between the two
FoMs can be selected, as a very low
corresponds with the maximum
PREE. In the case of
BED = 400 Wh/kg,
PREE is almost constant for the investigated interval of MTOW, and for lower values of
BED, a decreasing trend is still observed, as for the case of 600 nm.
Interesting considerations can also be made by evaluating the results for the case where
FoM is set equal to
PREE for the 400 nm design range. The results for the
PREE optima are reported in
Table 4, and the trend for the optimisation sets with the constraint MTOW
= is reported in
Figure 9. In particular, with respect to the reference case with a design range of 600 nm, in this scenario, increasing the MTOW resulted in combined improvements in both the
PREE and
for
BED = 500 Wh/kg; for the
PREE optimum, a
= 52 kg and a
PREE = 1.335 with a MTOW = 32,686 kg
f are obtained; the trend of
PREE with respect to MTOW (see the right part of
Figure 9) increases up to this maximum, then it starts to rapidly decrease. In the reference case (i.e., 600 nm), on the other hand, increasing the MTOW resulted in a very slight, almost imperceptible, peak with a similar trend to that seen for the case at
BED = 300 Wh/kg for the reduced range.
Reducing the range to 400 nm, therefore, would enable an effective implementation of hybrid–electric propulsion with
BED values reasonably achievable in the next decade. Configurations with potentially low-to-zero fuel consumption in the operating mission can be achieved by considering reduced values for the design range, which in any case would cover the largest share of the regional market [
24]. Furthermore, as demonstrated in [
36], design range extensions can easily be obtained for hybrid–electric aircraft with parallel powertrain architecture, at the expense of a slight oversizing of the thermal propulsion unit and/or a higher
in these extended-range conditions, considered as off-design routes.
Increasing the design range with respect to the reference case, on the other hand, leads to opposite observations. This is evident from the trends in
Figure 10 and the results in
Table 5, obtained by applying the optimisation procedure described in
Section 2, using
FoM equal to
for a design range of 800 nm. In addition to the obvious increase in
due to the higher energy demand of the route, there are substantial differences compared to the 600 nm and 400 nm cases. Specifically, increasing the MTOW does not introduce any significative benefit in terms of
for any
BED value (not even for the most optimistic forecast), as shown in the left part of
Figure 10. In fact, the opposite effect is obtained, with deteriorations in fuel consumption for all
BED values except for
BED = 500 W/kg, where an almost indifferent trend is obtained. In general, even in this latter case, increasing MTOW does not bring any benefit, as there is also an associated penalty in terms of the
PREE (see the right part of
Figure 10). With respect to the thermal benchmark, which exhibits an MTOW = 16,404 kg
f, an
= 1487 kg, and a
PREE = 0.859, reductions in
of 6.7% (with an increase in MTOW of 77%) are obtained for BED = 500 Wh/kg, hence not introducing significant overall benefits in this regard, nor are there any benefits in terms of
PREE (see the right part of
Figure 10).
To summarize,
Table 6 reports a concise comparison of the main performance of the
-optimised configurations varying BED and design range.
From the previous analyses and discussion, it is apparent that there are three distinct and interdependent boundaries that define a confined field for the effective implementation of hybrid–electric propulsion for regional transport aircraft. The first refers to battery technology development and points out that BED values (at battery pack level) of 500 Wh/kg must be achieved if effective and efficient integration of hybrid–electric propulsion on transport aircraft is to be envisaged. This is not sufficient unless the aircraft design requirements are properly tuned. In particular, benefits in terms of fuel consumption begin to be achieved if design ranges up to 600 nm are considered. Reducing the range to 400 nm leads to marked improvements in fuel consumption on the standard mission, at the expense of reductions in the aircraft operating capabilities. However, even with these reduced design range values (i.e., 400 nm), most of the typical routes in the current regional sector would be covered. Increasing the design range above 600 nm, on the other hand, would compromise the effectiveness of the integration of hybrid–electric propulsion, as there are no advantages to be gained in terms of fuel consumption and, therefore, no benefit from the reduction of greenhouse gas emissions viewpoint, which is indeed the driver for the development of this technology. The third element required for an effective implementation of hybrid–electric propulsion relates to the selection of figures of merit steering the design process. Specifically, it is highlighted that the technological and weight limitations of batteries need to be overcome through a paradigm shift in design development, in which increases in aircraft weight and reductions in energy efficiency must be taken into account if fuel consumption and related direct greenhouse emissions are to be minimised.