3.1. Simulation Methodology
The use of alternative fuels such as hydrogen, which have completely different properties compared to conventional liquid fuels, requires a fundamental new development for ICEs. Key challenges in the engine development process are the optimization of charge motion, mixture formation and combustion. Especially for fuels that have not been widely investigated yet, detailed analyses and a profound understanding of these complex processes are necessary. Complementarily to test bench investigations, 3D-CFD simulations offer almost unlimited potential for investigations. For this work, the 3D-CFD software QuickSim was selected, which was developed at the FKFS and IFS University Stuttgart. A more detailed description of the used model approaches can be found in [
13,
23,
24,
25] The following section provides a brief summary of the sub-models relevant to the present work.
Specifically designed for the virtual development of ICEs, QuickSim combines the commercial CFD solver of Star-CD with self-developed models for the injection, fuel, and combustion. The robust numerical framework is set up with a RANS approach in combination with a standard κ-ε turbulence model. Second-order spatial discretization (MARS) is selected with an implicit Euler temporal discretization scheme and for the pressure–velocity coupling, the Pressure-Implicit with Splitting of Operators (PISO) algorithm is used. Utilizing an innovative meshing and mesh motion methodology that does not necessitate remeshing during the complete engine cycle avoids mapping errors and leads to a significant reduction in computational time compared to other traditional 3D-CFD approaches. The combustion chamber is meshed with structured hexahedron cells, which are detailed enough to resolve the relevant flow effects so as to reduce numerical instabilities and enable larger time steps without compromising the accuracy [
13,
25]. By extending the simulation domain to the real test bench’s dimensions, and by calculating multiple consecutive operating cycles, the dependency on the initial and boundary conditions of the simulation is minimized.
Figure 5 shows the whole simulation domain, which includes all of the peripheries from the real test bench to correctly reproduce its behavior in the simulation.
Since the mixture formation directly affects the investigation of the combustion process in ICEs, a reliable 3D-CFD injection model is essential. For gaseous fuels in general, there are mainly two different approaches applied to simulate injection: Either a detailed injector model, where the inner flow of the injector is fully resolved, or a more pragmatic and simplified Lagrangian approach can be considered [
24]. Considering a PFI engine setup with multiple low-pressure injectors in the intake manifold, resolving the flow of the injectors would increase the computational effort significantly. For a more efficient development process, the macroscopic behavior, such as the propagation of the H
2 jet, the total penetration, and the displacement of air, must be prioritized. Therefore, a simplified Lagrangian injection approach is preferred for this simulation setup. Through this approach, the total number of cells can be reduced from many millions to only approximately 350,000. Due to these methodological simplifications, a good model calibration is required, for which optical measurements inside a spray chamber serve as a reference [
24].
The accurate description of the combustion process ensures reliable simulations of multiple consecutive engine cycles. In the 3D-CFD tool QuickSim, the caloric properties, as well as the LFS and the IDT, are calculated in advance for all possible temperature, pressure, and mixture composition conditions by using a detailed reaction mechanism in Cantera and are stored in comprehensive look-up tables [
23]. This approach avoids the necessity of performing a detailed chemical calculation for each cell in every simulated engine cycle. In reality, for most technical applications, there is not laminar but turbulent combustion, especially in ICEs. Turbulent eddies wrinkle the flame surface and accelerate the flame’s propagation due to the higher convection of reactants towards the flame [
27]. The increase from the laminar flame speed
SL to the turbulent flame speed
ST is described by the wrinkling factor
Kwrink, which accounts also for the increase in the effective surface of the wrinkled flame. In the context of this study, a semi-empirical formulation of
Kwrink is used, which was originally developed by Herweg and Maly [
28]:
This equation consists of multiple numerical inputs, where
rK is the kernel radius of the flame,
ll is the integral length scale of the flow field, and
Δt is the elapsed time since the ignition point. The component
ῡT represents the velocity relevant to the wrinkling factor, which, in this approach, is calculated via the combination of the main fluid’s kinetic energy and its turbulent intensity
u’. The resulting term is hereby described as
By assuming
u’ as an isotropic turbulent field, it is derived from the turbulence
k. The factor
kturb is additionally introduced to consider numerical and fuel-specific influences on the conversion of turbulence effects to scale the turbulence intensity. While the chemical reactions for hydrogen are less complex than for fossil fuels, a wide range of air-to-fuel ratios has to be taken into account. Especially for increased lambdas, the laminar flame speed
SL rapidly declines, and, according to Equation (1), this results in the anti-proportional behavior of
Kwrink with respect to
SL. This increased flame wrinkling phenomenon for leaner mixtures has also been observed in multiple studies, such as [
19,
20,
29,
30,
31].
According to the model of one-step flame propagation proposed by Weller [
32], and by introducing a flame progress variable, the position of the flame can be identified in the 3D-CFD mesh. This variable can take values between 0 and 1 and defines the extent to which a specific numerical cell has already been burnt. When using the approach of Weller in the context of a RANS simulation in combination with coarse meshes and relatively large time steps, an empirical formulation for flame wrinkling is required. The equation presented by Herweg and Maly [
28] is a relatively simple semi-empirical formulation for flame wrinkling and attempts to account for the microscopic flame phenomena. A more comprehensive description of Equation (1), which explains in detail which term refers to each stage of flame progression, can be found in [
13,
28].
The 3D-CFD tool QuickSim provides additionally a 3D auto-ignition model, which was specifically developed for the reaction kinetics approach. With the help of the detailed look-up tables for the ignition delay times of the mixture, it is possible to locally predict abnormal combustion events such as knocking, pre-ignition, or backfiring. The most common approach for self-ignition models is based on the evaluation of the pre-reaction state of the mixture. The formulation used in this work was originally proposed by Livengood and Wu [
33]:
For this formulation, τ is the individual ignition delay timing of the mixture in its current conditions inside the 3D-CFD cell. The integral length t is the elapsed time, and te is the time at the end of integration. With an additional transport equation for this knock integral, the temporal changes in the conditions and the mixture properties are considered as well.
3.3. Operating Points
The 3D-CFD investigations of the combustion process were performed for six operating points (OP) at 3000 RPM, among which three operating points are part of a load variation from 10 to 23 bar IMEP, while the other three operating points represent an air-to-fuel ratio variation for lambda values between 1.5 and 2.5. The intake air temperature T2 was kept constant at 40 °C, and, since there was no exhaust turbocharger within this test bench setup, both the intake pressure p2 and the exhaust pressure p3 were set to the same value. These settings were necessary to ensure that the resulting residual gas content in the cylinder and the pre-chamber was accurately reproduced, as they have a significant influence on the knocking behavior of the real engine. Moreover, a 50% mass fraction burned (MFB50) of 8 °CA after FTDC was aimed across all operating points, and the end of injection (EOI) was kept constant at −280 °CA.
For the load variation, the lambda values were kept constant at around 2.0. This means that the air and fuel demand increased for higher loads and had to be compensated for by a higher boost pressure and a greater amount of injected fuel.
Table 4 shows a comparison of the relevant engine values for the test bench and the converged 3D-CFD simulation after multiple consecutive simulated engine cycles.
The lambda variation was implemented at a constant engine load of 15 bar IMEP. Higher boost pressures provide more air mass to increase the lambda values, whereas the fuel mass remains more or less constant (see
Table 5). Differences in the engine’s indicated efficiency are the reason for the slightly higher fuel consumption at lower lambda values, because, typically, the wall heat losses are higher here [
26]. Moreover, in the case of lambda 1.5, the MFB50 is slightly delayed due to knocking limitations.
The calibrated simulations show good agreement for the different operating points. The geometries of the peripheral components play a decisive role in a single-cylinder engine in particular, as the acoustics inside the intake and exhaust system can lead to a significant difference during engine operation. The different boundary conditions for each load point and lambda affect the behavior of these pressure oscillations and the entire gas exchange process. For this reason, not only the cycle-averaged values are important for the simulation calibration, but also the comparison of the boost pressure, back pressure, and in-cylinder pressure with the indicated pressure curves from the test bench. The accurate reproduction of the geometric properties of the test bench periphery and the calibrated injection model enables the simulation to reproduce the same pressure curves as on the test bench. A more detailed comparison of the calibration process is shown in [
26,
34]. The analysis of the in-cylinder pressure and the overall combustion characteristics for different reaction mechanisms is given in the following section.