Abstract
Vertical axis wind turbine (VAWT) array design requires adequate modelling of the turbine wakes to model the flow throughout the array and, therefore, the power output of turbines in the array. This paper investigates how accurately different turbulence models using 2D computational fluid dynamics (CFD) simulations can estimate near and far wakes of VAWTs to determine an approach towards accurate modelling for array design. Three experiments from the literature are chosen as baselines for validation, with these experiments representing the near to far wake of the turbine. Five URANS turbulence models were chosen due to their common and potential usage for VAWT CFD: models k–ω SST, k–ω SST LRN, k–ω SSTI, transition SST, and k–kl–ω. In addition, the lifting line-free vortex wake (LLFWV) model was tested as an alternative to CFD for the far turbine wake where it was appropriate for use. The results for turbulent kinetic energy and vorticity were compared for the first experiment, whilst streamwise and cross-stream velocity were used for the other two experiments. It was found that none of the turbulence models tested or LLFVW produced adequate estimations within the methodology tested, however, transition SST produced the closest estimations. Further adjustments to the methodology are required to improve accuracy due to their large impact on results including use of 3D CFD, adjustment of surface roughness, and inlet flow characteristics.
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1 Introduction
Vertical axis wind turbines (VAWTs) are an alternative wind turbine design to the traditional horizontal axis wind turbine (HAWT) design. VAWTs have some potential advantages including omnidirectionality, lack of necessity of a pitching mechanism, and increased performance for arrays (Dabiri 2011). In the offshore context, they offer better stability for floating turbines due to their low centre of gravity because the generator can be placed at or below sea level. The potential for higher power density arrays (Dabiri 2011) allows for greater utilisation of regions which demonstrate geographical advantage such as higher wind speeds or more suitable topography which would reduce levelised cost of energy. However, there are also disadvantages such as lower power coefficient and a more complex basic design. These disadvantages may be hard to address as VAWTs present a difficult flow problem to model due to effects of dynamic stall and highly variable angle of attack of the blades, alongside the more three-dimensional nature of the flow and greater interactions between blades. Computational ability has increased and, therefore, accurately modelling this flow has become more viable for researchers, allowing for investigation of these disadvantages.
1.1 Simulations
Modelling VAWTs can be split into two categories: 2D and 3D. The effects of dynamic stall, angle of attack, and interactions between blades can be modelled in 2D for the common H-bladed VAWT, which is effectively an extrusion of a 2D pattern of aerofoils around a central shaft (Abdalrahman et al. 2017). However, 3D effects are also important due to the high aerodynamic impact of the struts from the shaft to the blades (Hand and Cashman 2017), alongside tip effects which have a greater impact for turbines with a lower aspect ratio (Galetta 2018). 3D effects are also more prominent in other VAWT designs such as Helical or Φ which cannot simply be considered as an extrusion of a 2D object due to their variation of aerofoil position with height. For H-bladed VAWTs, 3D effects are necessary to consider for a more accurate prediction of the power coefficient of the turbine (Gosselin 2015).
Computational fluid dynamics (CFD) is commonly used to model VAWTs, because it offers an accurate general-purpose method of analysing fluid dynamics problems. A major factor in the accuracy of CFD simulation is the turbulence model used, so careful consideration is required to ensure the most suitable choice of turbulence model. Large or detached eddy simulation (LES/DES)-based turbulence models offer supreme accuracy but require higher resolution meshes and a 3D approach, therefore, needing much higher computational resources (Rezaeiha et al. 2019a).
Alternatively, Reynolds averaged Navier Stokes (RANS) models can be used, which allow for faster analysis, including in 2D. Within RANS there are several popular models for the analysis of VAWTs, the most common option being k–ω SST (MacPhee and Beyene 2016; Balduzzi et al. 2016; Zanforlin 2018; Su et al. 2020; Kothe et al. 2020), followed by k–ε (Howell et al. 2010; Castelli et al. 2011; Lee and Lim 2015; Pan et al. 2020; Mohamed et al. 2020) and transition SST (Rezaeiha et al. 2018, 2019b; Asr et al. 2016). Previous studies have also used other models including Spalart–Allmaras which has shown to be inadequate (Daróczy et al. 2015; Danao et al. 2012), k–kl–ω (Daróczy et al. 2015; Arab et al. 2017), and corrections of k–ω SST (Danao et al. 2012) and transition SST (Almohammadi et al. 2013) such as the low Reynolds number and curvature corrected versions. There is also uncertainty regarding which RANS model provides the most accurate results, with some articles making opposing conclusions, particularly regarding k–ω SST and transition SST (Danao et al. 2014; McLaren et al. 2012; Daróczy et al. 2015; Rezaeiha et al. 2019b). A contrast also exists amongst the literature between which models better predict the power output of VAWTs and which better predict the wake characteristics, which is problematic given that accurate prediction of both is necessary for analysing arrays.
The 2D approach has some limitations which are demonstrated in Jiang et al. (2020), with the flow at the tips being significantly distorted, an effect which cannot be modelled in 2D and so requires a 3D approach. However, it can be seen that this has limited effect on velocity at the midplane for sufficiently high aspect ratio blades, so 2D results remain a valid estimation for wake velocity downstream at the midplane up to a certain point downstream providing the VAWT design does not use struts at or near the midplane as per Bachant and Wosnik (2016). Boudreau and Dumas (2017) find this point to be approximately 2 diameters downstream whilst Jiang et al.’s results and the results from Lam and Peng (2016) imply that this point occurs beyond 5 diameters downstream. The discrepancy is likely to be the result of differences in tip speed ratio which result in Boudreau and Dumas’ setup having greater vortex shedding due to the higher effective angle of attack of the blades as a result of the lower tip speed ratio compared to Jiang et al.’s experiment. Alongside, these are two experiments by Tescione et al. (2014) and Rolin and Porté-Agel (2018), where Tescione et al.’s experiment does not show the impact of tip effects at the midplane within the sampled region downstream, whilst Rolin and Porté-Agel shows an impact at the earliest sampled distance downstream, 2 diameters. Both Tescione et al. and Rolin and Porté-Agel show increased wake enlargement at the midplane which may be due to 3D effects, however, given that many 3D CFD results in the literature Lam and Peng (2016) and Boudreau and Dumas (2017) do not demonstrate this wake enlargement it is inconclusive whether using 3D CFD is currently a solution. Equally, this phenomena is not seen in all VAWT experiments so the cause remains unclear (Posa et al. 2016; Lei et al. 2017). This study will not consider the cause of this discrepancy and leave this for future research.
An alternative method to CFD is nonlinear lifting line-free vortex wake (LLFVW) implemented in the QBlade suite, which allows a 3D approach but with significantly reduced computational resources compared to both 2D and 3D CFD (Marten et al. 2018). This method is significant, because it allows for wake modelling which other rapid simulation methods like Blade Element Modelling do not allow for unless combined with CFD, making them much more computationally intensive.
1.2 Experiments
Several experimental methods can be used for the flow analysis of VAWTs. Wake characteristics are analysed by carrying out particle image velocimetry (PIV) or stereoscopic particle image velocimetry (SPIV). With PIV, the fluid is seeded with particles which are assumed to follow the same fluid dynamics as the fluid, the particles are then tracked through the flow using a camera. This allows for instantaneous tracking of fluid velocity along a two-dimensional plane, which for VAWTs is typically recorded at the mid-span of the blades. SPIV adds a second camera to track velocity in a third axis. Hot-wire anemometers can also be used which measure velocity in a single dimension and are typically used to measure the velocity across the horizontal axis of a wind tunnel. Laser and acoustic Doppler velocimetry or Cobra probes can also be used, however, these only measure velocity at a single point.
Buchner et al. (2015) investigated the blade wake at the point when the blade is furthest upwind at three different tip speed ratios (TSRs) using SPIV. Buchner et al. (2015) also compared their results against a 2D CFD model using k–ω SST, finding that the k–ω SST model is a poor predictor of wake characteristics including turbulent kinetic energy (TKE), dissipation rate, and vorticity, especially at TSR = 2.0. Tescione et al. (2014) used SPIV to measure the velocity field in the near-turbine wake up to 2 turbine diameters (D) downstream at TSR = 4.5. A partner study by Castelein et al. (2015) used the same experimental setup for the blade wake at several different rotational points at TSR = 2.0 and TSR = 4.5. Posa et al. (2016) studied near-turbine wake velocity using PIV up to 1D downstream at two TSRs (1.35 and 2.21). Posa et al. compared these results to a 2.5D CFD model using LES and found that the predicted wake velocity was higher than the experimental results but proposed that this was due to differences in the domains and poor aspect ratio elements in the mesh of the CFD model.
Peng et al. (2016) used hot-wire anemometers and a cobra probe to measure velocity downstream of the mid-span of the turbine. Peng et al. recorded results up to 10D, but at a lower resolution of only 1D. Lam and Peng (2017) conducted a study using two turbines in co-rotating and counter-rotating formations with the same methodology as Peng et al. (2016). Tescione et al. (2014) and Peng et al. (2016) also recorded results in the vertical direction, which enables validation of 3D CFD models. Ferreira (2009) also utilises hot-wire anemometry. Li (2016) used ultrasonic anemometers to measure wake angle in both wind tunnels and the field, measuring along two lines placed 1 and 2 turbine diameters behind the turbine, respectively.
1.3 Research gap
Studies on similar topics have been conducted previously such as Rezaeiha et al. (2019b) which investigated wake velocity prediction across seven turbulence models, including a comparison with Tescione et al. (2014). They found that transition SST offered the best results although the other SST-based models performed similarly overall. However, Rezaeiha only investigated the near-turbine wake and not the blade wake. Rezaeiha used a mesh of 402,999 cells but did not verify the mesh or meshing methodology for wake modelling downstream of the turbine, so it is unclear whether the results are a valid representation of the models’ performance. The study does not consider the impact of tip speed ratio and, therefore, changes in effective Reynolds number on accuracy, or the evolution from blade wake to the wake downstream of the turbine.
Lam and Peng (2016) also conducted a CFD study using Tescione et al.'s results, considering 2D and 3D simulations using the transition SST turbulence model, alongside a 3D simulation using improved delayed detached eddy simulation (IDDES). Lam and Peng showed that IDDES offered no advantage compared to 3D transition SST, however, 3D transition SST offered better predictions of the near-wake compared to 2D. This study does not consider differences between turbulence models using 2D CFD and focuses on the differences between 2 and 3D CFD rather than the accuracy of the models. It also does not consider the evolution of the wake from the blade to the downstream wake.
Daróczy et al. (2015) compare the performance of URANS turbulence models for 2D CFD against baseline experiments, but only considers the TSR/Cp curve and not the blade or turbine wake.
Whilst there have been comprehensive comparisons of turbulence models for 2D CFD of VAWTs in the literature there has been limited consideration for the wake and in particular how the wake evolves in the different turbulence models to affect the downstream wake estimations. The accuracy of predicting the downstream wake is key for developing array designs due to their high sensitivity to location (Barnes and Hughes 2019; Sahebzadeh et al. 2020).
This paper will investigate the CFD modelling of 2D flow effects around vertical axis wind turbines. Five turbulence models and LLFVW will be validated against three experiments, each experiment representing different regions of the VAWT wake. The results will then be used to investigate the effect of turbulence model on accuracy of wake prediction. Through understanding how inaccuracies in predicting wake propagation at the blade level affect the wake further downstream of the turbine, it will be possible to develop models which more accurately predict array performance and to minimise the computational time required to make VAWT array optimisation a more viable endeavour.
2 Methodology
This study will use experimental results from the literature as baselines to compare the accuracy of several turbulence models for predicting the propagation of VAWT wakes from near-blade wake to near-turbine wake.
Three experiments by Buchner et al. (2015), Tescione et al. (2014) and Castelein et al. (2015) were used to validate results of representative CFD simulations. These three experiments have been chosen as they represent different regions and conditions of a VAWT. Buchner investigates the near-blade wake at several tip speed ratios, TSR = 1.0, 2.0, 3.0, which are representative of typical operating TSRs of a VAWT. Tescione investigates the near-turbine wake which is important when considering the VAWT's surroundings, for example when investigating VAWT farms. Near turbine wake can be defined as up to 3D away from the shaft, because this region is commonly used for closely spaced arrays (Brownstein et al. 2019; Barnes and Hughes 2019; Sahebzadeh et al. 2020). Castelein investigates the near and far-blade wake which is the transition between the near-blade and near-turbine regions. These regions are visualised in Fig. 1. The experiments use turbines with high blade aspect ratios, struts far away from the midplane, and high or increasing tip speed ratios, which allow for the 2D CFD methodology to extend its validity further downstream from the turbine due to minimising the impact of 3D effects in the studied regions. This is confirmed for the Tescione experiment with tip vortex effects not reaching the midplane within the sampled region.
Five turbulence models were validated against these experiments. The models k–ω SST, k–ω SST LRN, k–ω SSTI, transition SST, and k–kl–ω as these are a combination of popular and increasingly popular choices in previous literature on VAWTs due to their accuracy and suitability to aerofoil flow problems combined with lower computational resource requirements. LLFVW was also used for the (Tescione et al. 2014) validation as it is suitable for the turbine wake but not blade wake.
The simulations were verified using mesh cell count and simulation length measured in number of turbine rotations. Other criteria including time step and pressure–velocity coupling has been chosen using the results and recommendations of previous literature.
2.1 Model setup
All simulations used the settings described in Table 1. Coupled was used as it allows for equal performance at larger time steps (Balduzzi et al. 2016) and faster convergence (Daróczy et al. 2015). Second-order discretisations were used due to the loss of accuracy from lower order formulations with some turbulence models (Almohammadi et al. 2013). Bounded second-order implicit was used for the transient formulation. The convergence criteria was set to 10–5 for all residuals and the number of iterations was set accordingly at 100 to ensure this was always met.
Table 2 lists the domain configuration for the simulations, including the shape and dimensions of the domain and rotating region. For the simulation based upon Buchner's experiment, the domain shape and dimension were chosen to match those used in Buchner's CFD analysis. However, a ring was used for the rotating domain as this allows for a significant reduction in mesh cell count without affecting results as the PIV results were measured at the upwind-most position where the centre of the rotating domain will have an insignificant effect on results. For the Tescione and Castelein domain, the inlet and width dimensions were chosen to match Lam and Peng (2016) which conducted another 2D CFD validation of the Tescione experiment. An outlet length of 20D was used.
All CFD investigations was completed in ANSYS workbench versions 18.2 and 2019 R1, using DesignModeler for the geometry creation, ANSYS Meshing and FLUENT for meshing, FLUENT for the CFD simulations, and ANSYS Post-Processing to create any images of the CFD results.
The other setups were designed appropriately for the Buchner validations, and then again for the Tescione and Castelein validations. A single combined validation was sufficient for the latter two due to using the same experimental setup.
For QBlade, polars were determined for − 25° to 25° then extrapolated using the Viterna method. The LLFVW settings remained at default or the appropriate conditions to match the experiment, except for the panel method being set to sinusoidal with 20 panels, the tower being included with appropriate width and height, and turbulent wake convection being turned on.
2.2 Buchner validation setup
Buchner tests a variety of TSRs (1.0, 2.0, and 3.0) using the same rotational speed but varying the inlet velocity (15 m/s, 7.5 m/s, and 5 m/s). The models were compared on turbulent kinetic energy (TKE), turbulence dissipation, and vorticity.
A domain matching Buchner's CFD setup was used, with an outer domain diameter of ten diameters. The struts were not replicated due to the use of a 2D domain, which also prevents analysis of tip effects, however, the position of the PIV slice at mid-span minimises the effects of the struts and tip effects on the results. The shaft was also not included as the position of the blade at the chosen sampled rotational position by Buchner, on the far upwind side of the turbine, means the effect of the shaft is negligible. An inner rotating domain for the turbine with a diameter of 2D was used as while 1.25D was found to be sufficient (Rezaeiha et al. 2017), the referenced study used a turbine with a significantly lower solidity than the turbine used by Buchner, which will impact the size of the blade wake. The larger high-density mesh area will account for this to ensure greater accuracy of the blade wake. 50 inflation layers with a growth rate of 1.09 were applied to the blades with a first layer height of 1.955 × 10−5 m to provide y+ = 1 which is necessary for good performance with SST models. The singularity at the trailing edge of the aerofoil was treating by trimming the trailing edge.
These settings were used to produce meshes with cell counts of 47,679 (low), 220,081 (medium), and 782,263 (high) seen in Fig. 2, with the high cell count mesh created from the medium mesh using the refinement tool in FLUENT. A rotational step of 0.5° was used as recommended by Rezaeiha et al. (2017). Simulation lengths of 1.5, 5, and 10 rotations were tested to determine the point of convergence.
Skin friction coefficient along one side of the blade length measured as fraction of chord was used to verify convergence of the mesh cell count and time step as this is a measure of the effects of flow against the blades and so can be used as a quantitative measure of the convergence of the wake. This is plotted in Fig. 3 where ten rotations using the medium density mesh and five rotations using the high-density mesh produce the same curve, so the medium mesh is chosen.
The different turbulence models and the experiment will be quantitatively compared upon the area of the wake, measured using a colour threshold in the software ImageJ, with the areas normalised against the area of the blade in the image.
2.3 Tescione and Castelein validation
Tescione tests a single condition with a fixed freestream velocity of 9.3 m/s and a TSR of 4.5, this was repeated in these simulations. The result of the experiment was the streamwise and cross-stream velocity values. While Castelein uses a slightly lower freestream velocity of 9.1 m/s, however, the small change this causes to Reynold’s number means the effect on results is insignificant.
Tescione used a wind tunnel test section with measurements of 13.7D × 6.6D × 8.2D and this was replicated in the 2D models using a 13.7D × 6.6D test section. As Tescione does not state the location of the turbine with this domain, it was placed 5D downstream from the velocity inlet, the same as used by Lam and Peng (2016) for another validation of Tescione. The shaft was replicated in the 2D model as it effects downwind wake velocity, as shown by the images produced by Tescione et al. (2014). The struts were not replicated due to the position of the stereoscopic particle image velocimetry (SPIV) slice at mid-span minimising their effects on the results and because it is not possible in 2D simulations.
A high cell count mesh of 1,351,811 cells was produced with a dense section following the turbine to accurately capture the near-turbine wake, which was not necessary for the Buchner validation as the area of interest was limited to the near-blade wake and so did not extend downwind of the turbine region. The high cell count combined with using the same meshing technique as for the Buchner simulation ensures converged results. Y+ value was set to 1. A time step of 1 × 10−4 s was used, equivalent to 0.5°, which is sufficient for the high TSR scenario used here (Rezaeiha et al. 2017; Danao et al. 2014). The simulations were run for 15 revolutions or until there was no change at 3 diameters downstream of the turbine centre after 1 revolution, whichever required the highest number of revolutions. This is much higher than Buchner due to the necessity of further wake propagation to produce converged results in the downstream wake. For the time-averaged results, a single sample was taken every time step for one revolution using the Data Sampling for Time Statistics feature in FLUENT.
For comparing simulation results against Tescione, the maximum percentage and absolute deviation from the experimental results will be recorded, whilst for comparisons against Castelein, the area of comparable colour bands will be recorded.
3 Results
3.1 Near blade wake
Buchner produced results for turbulent kinetic energy (TKE), dissipation rate ε, and vorticity at TSRs 1.0, 2.0, and 3.0. Out of these both TKE and vorticity have been replicated with CFD simulations using the different models.
First, the quantitative results can be considered using the size of the wake, shown in Tables 3 and 4.
Large deviations can be seen between nearly all simulations and the experiment, with significant variation between the different measures of wake size also. The largest deviations occur for positive vorticity at TSR = 2.0 with overestimations greater than 140% for most models, with the exception of transition SST which demonstrates its improved performance in the laminar-to-turbulent transition region. The normalised wake area for the turbulence models for negative vorticity is relatively consistent, with the percentage difference between the models decreasing as TSR increases. Compared to the other turbulence models and the experiment, k–kl–ω tends to overestimate the turbulent kinetic energy wake area whilst producing lower estimates of positive vorticity.
In terms of the average absolute deviation shown in Table 4, transition SST offers the lowest absolute deviation, followed by k–kl–ω. Both of these models have lower average deviation due to improved performance in a number of circumstances compared to other models rather than consistently improved accuracy.
The results can then be considered qualitatively to understand some of the causes of these deviations.
The upper left image in Fig. 4 shows Buchner’s PIV results for turbulent kinetic energy at TSR = 1.0, showing a wake with a height of 0.11 m, a circulation at the leading edge which is approximately at a right angle to the chord, one vortex at the trailing edge and one vortex above the three-quarter chord position, and a tail which extends from between the two vortices.
The other images in Fig. 4 show the CFD results for the four turbulence models at TSR = 1.0. Transition SST produces the closest representation of the wake with vortices at the trailing edge and above the three-quarter chord position. A faint tail is also found alongside the leading edge circulation. However, it fails to predict the angle between the leading edge circulation and chord, and underestimates the size of the wake and TKE. The other models fail to predict the position of the vortices but predict a stronger tail. The k–kl–ω model also produces a better prediction of the leading edge circulation.
For vorticity at TSR = 1.0 in Fig. 5, two vortices are seen with a leading edge circulation and trailing edge circulation. The upper vortex has negative vorticity, while the trailing edge vortex has positive vorticity. A small triangle of positive vorticity is also seen behind the leading edge circulation.
As shown in the other images in Fig. 5, vorticity is overestimated significantly. The k–ω SST models produce the most similar shape of the wake overall. k–kl–ω produces a more accurate prediction at the leading edge with a thinner leading edge circulation and a smaller triangle of positive vorticity, but underestimates the size and impact of the trailing edge vortex as shown in the quantitative results.
Figure 6 shows the TKE experimental result at TSR = 2.0, with a separation of very high TKE stemming from the leading edge, followed by reattachment, then a tail originating at the trailing edge.
Transition SST is the best predictor of the leading edge separation amongst the models shown in Fig. 6 but significantly underestimates the size of the separation and does not predict the reattachment. The size of the tail is also underestimated significantly.
The experimental vorticity result in the top left of Fig. 7 shows the same pattern as the turbulent kinetic energy result, with a negative vorticity leading edge separation followed by reattachment. At the trailing edge, the tail is split into an upper negative vorticity region and a lower positive vorticity region.
Vorticity is again significantly overestimated in the CFD shown in the other images in Fig. 7 compared to the experimental results and the overall prediction is poor. All models predict the negative vorticity upper tail and positive vorticity lower tail, although k–ω SST LRN and k–kl–ω predict shorter but wider tails.
The experimental result for turbulent kinetic energy at TSR = 3.0 shown in the top left of Fig. 8 has a nearly flat wake from a separation close to the leading edge, with another trailing edge separation that produces a tail. In the vorticity map in Fig. 9, there is a positive vorticity lower tail and negative vorticity upper tail from the trailing edge.
All the models in Figs. 8 and 9 fail to predict the position of the initial separation, with all but k–ω SST estimating occurrence of separation at one-third chord. From the vorticity maps, it is seen that this is due to a positive vorticity region covering the leading edge, which pushes separation backwards. These differences may be due to surface roughness on the experimental blades which can affect separation (Iverson et al. 2019).
Overall, transition SST offers the most robust performance out of the tested turbulence models, however, accuracy is still poor for the blade wake so other modelling techniques may be required for near-blade wake analysis.
3.2 Near turbine wake
The Tescione experiment provides results of the wake surrounding and closely following the turbine, investigating time-averaged streamwise and cross-stream velocity.
First, the deviation between the simulation and experimental results can be considered in Table 5 for streamwise velocity, where transition SST demonstrates the smallest deviation from the experimental baseline at all distances downstream. However, the difference in accuracy between the turbulence models is limited with predictions from both k–ω SST and k–kl–ω remaining within 1% of Inlet Velocity. QBlade shows poor results with significantly larger deviations from the experiment. All models demonstrate increasing error from the experiment further downstream.
In Table 6, the cross-stream velocity is considered, showing that k–kl–ω offers the lowest error from the experiment up to 2.5R downstream. Then, transition SST offers the best accuracy at 4R downstream, with k–ω SST LRN and k–kl–ω offering slightly reduced accuracy.
Combining the streamwise and cross-stream velocity errors in Table 7, both transition SST and k–kl–ω offer good accuracy with k–kl–ω offering improved accuracy up to 2.5R downstream. This may indicate that transition SST is more appropriate for arrays where the turbines are placed greater than 2.5R apart, whilst k–kl–ω is appropriate for distances up to 2.5R. k–ω SST may be useful to initialise simulations due to being less computationally intensive, followed by switching to transition SST or k–kl–ω.
To understand the cause of the deviations, the graphs and contour maps of streamwise velocity can be considered, with markers representing sampled points.
From the experimental results in Fig. 10, it is shown that the wake in the experiment has reducing velocity further away from the turbine and there is a greater velocity deficit to the upwind stroke side of the turbine (positive X values), which increases further away from the turbine. The minimum velocity point moves from 2.5 m/s at approximately x = + 0.05 m for 1.5R downstream to 1.8 m/s at x = + 0.25R for 4.0R downstream.
The turbulence models show good estimations of the downwind stroke time-averaged streamwise velocity (negative X values) but fail to predict the greater deficit on the upwind stroke as seen in Fig. 11. This inaccuracy becomes greater further downwind. This has been seen in other research for 2D and 2.5D VAWT simulation by Bachant and Wosnik (2016) and Rezaeiha et al. (2017), though appears to be solved using a 3D approach (Lam and Peng 2016). It should be noted that Rezaeiha's paper uses Tescione's experiment as their experimental reference, and Bachant's turbine is at the same scale with similar magnitude of blade Reynolds number. Further research needs to be conducted at commercial scale Reynolds numbers of 107 to determine whether this is a factor in accuracy of prediction of the turbine wake for utility scale turbines.
k–ω SST and transition SST produced the most accurate results, with transition SST better predicting the wider low-velocity region on the upwind side from x = 0.2 m to 0.5 m for 1.5R and 2.5R, and x = 0.1 m to 0.5 m for 4.0R. k–kl–ω showed a droop on the downwind stroke side compared to the experiment and other turbulence models. It also showed a smoother wake profile throughout the rotations which could affect results for farm design as the intra-rotation fluctuations may alter power output of downwind turbines in some circumstances. Using cubed root of the mean of the cubed velocity fields would help designers account for this as this measures the average power at a given point (Wahl 2007). This relationship also means there would be relatively little difference in terms of power prediction for downstream turbines between k–ω SST and transition SST, because the regions where their predictions differ have low velocities.
Considering cross-stream velocity in Fig. 11, better accuracy is seen at smaller distances downwind, with k–ω SST LRN producing the most similar results to the experiment at 1.5R downwind, although the gradient of the velocity change is lower than expected from the experimental results. At 2.5R downwind, all models except for k–kl–ω show very oscillatory behaviour so there is no clear better turbulence model for predicting cross-stream velocity at this distance downstream. At 4.0R, the oscillatory behaviour becomes an even greater issue. For downwind turbines in the mid-wake, especially on the upwind stroke side, the cross-stream velocity constitutes a significant component of the total velocity vector, so accounting for this in turbine placement and variable pitch algorithms will be necessary to ensure optimal operation.
The results can also be compared against previous CFD in the literature for the Tescione et al. (2014) experiment such as Rezaeiha et al. (2019b) and Lam and Peng (2016) shown in Fig. 12. Lam and Peng’s results using the k–ω SST model demonstrate an overestimation at all points whilst Rezaeiha, Montazeri, and Blocken shows good agreement or small overestimation in the negative X region, whilst k–ω SST and transition SST in the current study underestimate between − 0.4 and − 0.1 m, with transition SST showing a greater deviation. In the positive X region, the current study demonstrates a significantly reduced deviation from the experiment using k–ω SST and transition SST compared to Lam and Peng, and Rezaeiha, Montazeri, and Blocken’s use of the same models. The oscillation at the centre in Rezaeiha, Montazeri, and Blocken’s results is also not seen in either the current study or Lam and Peng. This may be due to the choice of pressure–velocity coupler or the different meshes used, because these studies use similar methodologies otherwise.
3.2.1 Streamwise velocity wake visualisation
By inspecting the full plane of the wake, it is possible to visualise characteristics of the flow to help further understand the velocity graphs. Instantaneous values were used here for the CFD results.
It can be determined by inspection of Fig. 13 that the k–kl–ω model provides the most similar prediction of the instantaneous inner wake streamwise velocity with the other models failing to predict the more cohesive wake formation seen in Tescione's results. All the models overestimate the velocity at the edges of the wake, and k–kl–ω predicts a much smoother wake pattern than the experiment and other models. This is an issue for array design if the outer wake is an important variable in the performance of downwind turbines, and in a 3D scenario, there will be additional effects from wake contraction in the Z axis alongside tip vortex effects which are not present in the 2D simulation.
All models underestimate the velocity deficit caused by the shaft, with transition SST producing slightly higher velocity predictions than the other models. The SST models including k–ω SST, k–ω SST LRN, and transition SST are better predictors of the blade wake velocity with the impact still being accurately predicted until the third wake artefact downstream. The LRN model produces wavy sprites at the wake edge, however, while the experimental results show smoother sprites, so the standard k–ω SST and transition SST are better in this regard.
As shown in the velocity graphs also, the wake tends towards the centre or downwind side in the CFD models, whereas it tends further towards the upwind side on the experiment.
Differences occur in the visualised wakes due to inaccurate replication of the contour boundaries, as while the contour colour scheme has been replicated it is not a perfect copy. In the future, it would be preferable to use a scheme with smaller velocity bands and a larger colour gradient to improve comparability.
3.2.2 Cross-stream velocity wake visualisation
From Fig. 14, a significant departure from the experimental results is seen in all turbulence models. All models show smaller regions with cross-stream velocity near zero, alongside larger areas of negative velocity on the upwind side and positive velocity on the downwind side.
3.2.3 Discussion of Tescione validation
All the CFD models show good prediction of wake velocity on the upstream side of the turbine region, however, transition SST has a more accurate prediction on the downstream side. Wake artefacts from previous revolutions of the blade with the turbine region are positioned further downstream than their equivalents in the experimental results, and they have a smaller radius of curvature compared to the experiment also. This makes any comparison difficult as any interaction between past blade wakes and the rotating blades could alter results significantly.
There is also a repetition of k–kl–ω producing very different results compared to the other turbulence models, showing a lower cross-stream velocity on the edges of the wake compared to the experiment, in contrast to the high streamwise velocity in these areas.
The difference in these results compared to Rezaeiha et al. (2017) could be due to two variables: meshing or pressure–velocity coupler. The mesh used here has a much higher number of cells compared to Rezaeiha's (1,351,811 vs. 402,999) and in particular, this mesh uses a refined wake zone which was not used by Rezaeiha who only refined around the blade regions. The other change is that Rezaeiha used the SIMPLE pressure–velocity coupler whereas coupled was used here. A verification was conducted to determine whether this was the cause of the difference in results, however, the difference was negligible as shown in Fig. 15.
Overall, transition SST offers the most accurate model, however, users should be aware of velocity being overestimated in the upwind side wake. k–ω SST offers a good alternative for conducting a large number of simulations due to its lower computational time and similar accuracy. It is also clear that small deviations in methodology can make a significant difference for VAWT wake prediction as shown by the disparities in results between the current study, Rezaeiha et al. (2019b) and Lam and Peng (2016).
3.3 Far blade wake
Castelein examines the blade wake at different azimuthal positions at two TSRs, however, here only one TSR (4.5) will be investigated.
Table 8 considers the size of comparable regions of the blade wakes, divided into high-velocity regions above 6.5 m/s and low-velocity regions below 6.5 m/s. The size of the wakes are normalised against the area of the blade and a ratio between the size of the two regions is also provided to improve comparability and reduce the impact of any measurement inaccuracies. Results for the experiment at 90° and 135° are not provided due to insufficient data available from the original experiment.
It can be seen that at 45° and 270°, there is good agreement between the turbulence models, whilst at 180° k–ω SST and transition SST agree with each other but disagree with the similar results of k–ω SST LRN and k–kl–ω that produce a ratio closer to the experimental result. The deviation from the experiment at most positions is poor, although k–kl–ω and k–ω SST LRN demonstrate significantly improved accuracy at 180°, and transition SST at 315°. k–kl–ω produces very poor estimates at 0° compared to the other models due to significantly overestimating the size of the high-velocity region.
The average deviations are shown in Table 9, with transition SST offering the lowest deviation. k–kl–ω has a very high deviation due to the poor estimate at 0°. This deviation at 0° may have contributed to the streamwise velocity underestimate on the downstream wake side in the Tescione validation.
The cause of the quantitative results can then be evaluated qualitatively. In Fig. 16 the experimental velocity values as a ratio of freestream velocity are shown. The original colour scheme used helps to highlight certain flow characteristics but it can also make simulation results look very different if the values are slightly different.
Good agreement is shown between the turbulence models and the experiment at 0° as shown in Fig. 16. At 45° the overall structure of the simulated wakes are similar to the experiment, however, the low-velocity separation is elongated compared to the original teardrop shape in the experiment, as shown in Fig. 17. Results at 90° were not provided for the experiment but good agreement was shown between the turbulence models. Overall, the results for the SST models had insignificant differences between each other, and with all differing significantly from the experiment.
At 135°, a small delay in the separation bubble on the inside of the blade is seen in Fig. 18. At 180°, a small high-velocity region is found at the trailing edge which is not present in the experimental results. Using k–kl–ω, an improvement is seen with a reduction in the size of the high-velocity separation bubble, and increase in the low-velocity separation, at both 135° and 180°, however, they are still different in size to the experimental results as seen in Figs. 18 and 19.
At 225°, a much larger high-velocity region is found at the inner side of the trailing edge of the blade compared to the experiment, seen in Fig. 20. At 270°, the SST turbulence models fail to predict the small separation bubble on the inside of the blade which results in a higher velocity region on the CFD results, as shown in Fig. 21. This issue continues at 315°, shown in Fig. 22.
In all simulations at the 270° position, the direction of the separation bubble at the trailing edge is reversed compared to the experiment, meaning there is a slight difference in the effective angle of attack of the blade. This indicates that there could be a skewed flow in the experiment, which may also have exaggerated other differences between the experiment and CFD results. It is unknown whether this may also be an issue in Tescione's experiment.
At 135° and 225–315°, k–ω SST predicts wider and longer tails than the other models, which is more similar to the experimental results.
3.3.1 Discussion of Castelein validation
Overall, a better prediction of the far-blade wake is seen with transition SST which is expected given that this is similar to the instantaneous results from the Tescione validation, however, there is still significant inaccuracy. It is unclear whether this is due to limitations of the turbulence models, 3D effects, or variables which have not been accounted for.
The difference in results between the turbulence models and the experiment may partially be due to differences in effective angle of attack of the blade, either as a result of the difference in inlet velocity, the simulation setup, or the wind tunnel setup. Another possible cause is the lack of accounting for surface roughness in the simulations, as Zhang finds that blade wakes are affected significantly by surface roughness (Zhang 2018).
4 Conclusion
From the validations of the three experiments, it has been shown that the 2D modelling techniques used are insufficient for universally accurate prediction of VAWT wakes from near-blade to near-turbine regions. However, this may partially be due to compounding factors in the experiments which have not been accounted for, such as surface roughness and flow in the wind tunnel.
It was possible to identify conditions where 2D CFD produced more accurate results. It was found that the commonly used k–ω SST and k–kl–ω produce satisfactory results to be used as a faster initial estimate for farm design. Transition SST offers slightly improved accuracy in most circumstances but takes a longer amount of time than k–ω SST. k–kl–ω can offer improved accuracy in some circumstances including the turbine wake less than 2.5R downstream and for predicting turbulent kinetic energy at low tip speed ratios but it can have poor accuracy in other circumstances as seen at 0° for the high tip speed ratio Castelein validation.
Prediction of VAWT wakes was investigated at scales from the near-blade wake to the near-turbine wake, and across different tip speed ratios to determine the most suitable turbulence model for CFD analysis of VAWTs. CFD simulations were conducted based upon three experiments found in the literature which were chosen to represent these conditions.
The necessity of stringent verification procedures for CFD studies of VAWT wakes has also been demonstrated, with very high cell counts being required for good fidelity, and more rigorous definitions necessary for experimental setups if they are to be replicated.
Future research should consider surface roughness and other potentially compounding factors in the experimental setup in VAWT CFD validation, for both 2D and 3D simulations. This may require experimental researchers to be more stringent in defining their setup when they publish their results, such as using a surface roughness comparator to measure surface roughness of the blades used.
-
The modelling techniques employed in this study were insufficient for universal accurate prediction of VAWT wakes but scenarios where improved performance is seen have been shown
-
Compounding factors are likely to affect results such as insufficient recreation of the baseline experiments in the simulation such as surface roughness and inlet flow
-
Future research requires stringent verification procedures and should attempt to measure and account for compounding factors
Availability of data and materials
Abbreviations
- ε :
-
Turbulence dissipation
- 2D:
-
Two dimensional
- 3D:
-
Three dimensional
- CFD:
-
Computational fluid dynamics
- D :
-
Diameters
- HAWT:
-
Horizontal axis wind turbine
- R :
-
Radius
- RANS:
-
Reynolds averaged Navier Stokes
- SPIV:
-
Stereoscopic particle image velocimetry
- TSR:
-
Tip speed ratio
- TKE:
-
Turbulent kinetic energy
- VAWT:
-
Vertical axis wind turbine
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Acknowledgements
This work was supported by an EPSRC Doctoral Training Scholarship.
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This research was funded by the EPSRC (Grant no. 2119005).
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Barnes, A., Marshall-Cross, D. & Hughes, B.R. Validation and comparison of turbulence models for predicting wakes of vertical axis wind turbines. J. Ocean Eng. Mar. Energy 7, 339–362 (2021). https://doi.org/10.1007/s40722-021-00204-z
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DOI: https://doi.org/10.1007/s40722-021-00204-z