Journal of Sustainable Architecture and Civil Engineering 2017/2/19
92

*Corresponding author: jennifer.keenahan@ucd.ie

Sustainable Design using 
Computational Fluid 
Dynamics in the Built 
Environment – A Case Study

http://dx.doi.org/10.5755/j01.sace.19.2.17991

Jennifer Keenahan*
Arup, 50 Ringsend Road, Ringsend, Dublin 4, Ireland and University College Dublin  
Newstead, Belfield, Dublin 4

Reamonn MacReamoinn, Cristina Paduano
Arup, 50 Ringsend Road, Ringsend, Dublin 4, Ireland

Received  
2017/04/19

Accepted after  
revision 
2017/05/30

Journal of Sustainable 
Architecture and Civil Engineering
Vol. 2 / No. 19 / 2017
pp. 92-103
DOI 10.5755/j01.sace.19.2.17991 
© Kaunas University of Technology

Sustainable Design 
using Computational 
Fluid Dynamics in the 
Built Environment – 
A Case Study

JSACE 2/19

In recent years, end users have become more concerned with the human experience and the 
personal comfort of the individual is becoming more important in the design of the built environment. 
Computational Fluid Dynamics (CFD) is a tool that permits assessment of personal comfort. CFD is a 
stream of fluid mechanics that utilises numerical methods to analyse and solve problems involving 
fluid flows. While research applications of CFD are developing, as is the use of CFD in the aerospace and 
Formula1 industries, the use of CFD in Civil Engineering applications is currently at the cutting edge. 
This paper will investigate the use of computational fluid dynamics as a complementary approach to 
wind tunnel testing for pedestrian comfort. The results showcased here were determined through a 
consultancy project by the team at Arup, Dublin. On determining potential wind problems, mitigation 
measures were proposed and tested in CFD to prove that the mitigation measures were effective. These 
proposed changes were incorporated into the final design and as a result planning permission was 
awarded for the development. This work is exemplar of how, from the very conception of the project 
design, new technological advances lead to a better built and sustainable environment for all.

Keywords: Built Environment, CFD, Pedestrian Comfort, Wind, Wind Tunnel Test. 

The design of urban environments ought to focus on the effects of the design on the outdoor built 
environment, in addition to focusing on the envelope of the building and on the quality of the indoor 
environment. To date, the outdoor built environment has received relatively little attention by de-
signers, particularly with respect to wind. The negative effects of windy environments were first dis-
cussed by Wise (1970) who noted the presence of vacant shops where shoppers were discouraged 
due to the windy environment. Separately, Lawson and Penwarden (1975) noted the deaths of two 
elderly ladies who were victims of windy gusts near a high-rise building. It is evident that the risks 
and consequences of unfavorable wind environments for pedestrians cannot be overstated. 

The main source of pedestrian discomfort is related to the force of the wind felt on their body and 
their clothing as additional effort is required to negotiate the wind. The Beaufort scale was the 
first empirical measure that related wind speed to observed conditions, it has been presented 
and incorporated in wind comfort studies by (Penwardon, 1973 and Soligo et al., 1998). Other 
authors (Penwardon et al., 1975 and Murakami and Deguchi, 1981) propose threshold wind ve-

Introduction



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Journal of Sustainable Architecture and Civil Engineering 2017/2/19

locities for pedestrian wind comfort. More detailed comfort criteria reflecting individual opinions 
on acceptable frequencies of occurrence of various wind speeds have been proposed in Isyumov 
& Davenport (1976), Apperly and Vickery (1974) and Melbourne and Joubert (1971). Later, grades 
of comfort are introduced related to the probability that a threshold wind speed may be exceeded 
(Willemsen and Wisse, 2007).

The Lawson Comfort Criteria (Lawson and Penwarden, 1975; Lawson, 2001) quantifies an individ-
ual’s annoyance with the wind. It enables the level of pedestrian discomfort to be evaluated based 
on pedestrian activity, wind speed and frequency of occurrence. A wind is acceptable if it goes un-
noticed, unpleasant if it is noticed but it does not prevent the area from being used for its designat-
ed purpose, and annoying when it is of sufficient strength and frequency to prevent the area being 
used for its designated purpose. Certain building configurations may give rise to intense local wind 
flows. Buildings that stand taller than their neighbors collect the wind over much of their height 
and direct it towards the ground. Intuitively, given that wind speed increases with height, the taller 
the building, the faster the wind speeds delivered to ground level (Lawson, 2001). The funneling 
of wind through narrow gaps between buildings can also cause unpleasant wind environments.  

To move towards a long-term sustainable built environment that is useable by pedestrians, it is 
necessary to determine the risk and occurrence of possible zones of unacceptably high pedestrian 
discomfort. It is crucially important that appropriate design decisions are made to eliminate such 
zones. While the challenge of wind-induced discomfort of pedestrians is not new, more modern 
types of buildings and open space configurations have evolved to create potentially even windier 
environments. Typically, such configurations involve tall buildings rising well above the surround-
ing built environment and adjacent to open spaces such as plazas and malls (Simiu, 1996). 

There are many design considerations that architects, engineers and planners take into account to 
mitigate windy conditions in the built environment. The orientation of commercial and residential 
buildings, the selection of the type of balcony (winter-garden or re-entrant balcony) relative to the 
direction of the prevailing winds and the inclusion of wind canopies and shelters are some exam-
ples that markedly improve the wind environment for the end users and pedestrians. 

Urban authorities and councils are beginning to recognize the importance of pedestrian wind comfort 
and wind safety. The Dutch Wind Nuisance Standard NEN 8100 (NEN, 2006), to the best knowledge of 
the authors, is the first standard in the world to account for pedestrian wind comfort in the built envi-
ronment. It is noteworthy that the standard unambiguously permits the designer to choose between 
wind tunnel experimentation and CFD modelling to assess the wind environment (Blocken et al. 2012).

Flachsbart (1932), concluded that simulations of the behavior of wind around buildings should be 
conducted in wind tunnels. Wind tunnel testing is now a long-established approach and the knowl-
edge and experience gained over the years has established wind tunnel testing as the traditional 
method for conducting wind analysis. However, wind tunnel testing is not without its short-com-
ings. For instance;

 _ Wind tunnels requires physical equipment to collect the data. As a result, it is only possible to 
monitor the flow field at a limited number of locations and it is difficult to measure the pres-
sure field and velocity field at the same time. Furthermore, the presence of the measuring 
device can often disrupt the flow. 

 _ For a truly representative model, the Reynolds number should be similar for the model as 
for the prototype. However, the reduced scale models used in the analysis of tall or long-
span structures would require impossible air flow velocities though the tunnel to ensure 
Reynolds number consistency. 

 _ Time and effort is required to develop a scale model for the wind tunnel test, this renders 
them unsuitable to the earlier stages of the design process when the design is in greater flux. 

 _ Wind tunnel estimates from different wind tunnels can vary widely.



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With the advent of computational power and the capability of numerical methods like Finite Ele-
ment Analysis, it is now possible to accurately simulate wind flow conditions in a virtual environ-
ment. Computational Fluid Dynamics (CFD) is an advanced modelling technique that establishes 
a basis to solve problems of fluid flow. CFD solves partial differential equations in continuum 
mechanics using numerical techniques. The equations governing fluid motion are based on the 
fundamental physical principles of the conservation of mass, momentum and energy. CFD dis-
cretizes the overall problem into many small volumes that can be solved more easily (Ferziger, 
2002). Combining the solutions from these small volumes permits the generation of a complete 
solution. 

CFD has been successfully applied in many areas of fluid mechanics including, heat and mass 
transfer (Lien, 2012), chemical reaction and combustion (Senveli, 2014), aerodynamics of cars 
and aircrafts, and pumps and turbines. Applications of CFD to the built environment include wind 
modelling and the dynamics response of structures (Montazeri, 2013) ventilation (Meroney, 2009) 
fire, smoke flow and visibility (Senveli, 2014) dispersion of pollutants and effluent (Prasad, 2013) 
and heat transfer in buildings (Kobayashi, 2003). Traditionally, the interaction of these phenomena 
has been carried out experimentally, using scaled models and short calculations. 

Computational Wind Engineering (CWE) is a branch of CFD concerned with the behavior of wind. 
Similar to wind tunnel tests, it can be used to understand the interaction of wind flow through an 
urban environment and the effect of a proposed development on the local wind microclimate.

In CFD the problem is expressed as a mathematical model and is solved iteratively using numer-
ical methods this gives abundant benefits over the physical wind tunnel, including:

 _ The entire flow field is solved simultaneously in CFD and therefore, it is possible to collect 
results from anywhere within the computational domain without influencing accuracy.

 _ The scale of the model is irrelevant in CFD modelling as the computational domain can be 
set to any scale. As a result, CFD does not suffer from any issues with Reynolds number 
violation. 

 _ Generally, CFD software packages interface easily with computer aided-design (CAD) pack-
ages. Should changes in design be necessary, it is relatively easy to adjust a CFD model 
due to these new design specifications and therefore, CFD is better integrated into iterative 
design processes. 

However, CFD is not without its disadvantages. For instance, it is difficult to model free stream tur-
bulence in CFD and it can be challenging to accurately model flow separation and free shear lay-
ers. If it is possible to verify and validate a CFD model using wind tunnel testing as a benchmark, 
there is potential to examine a greater variety of flow configurations due to greater flexibility of 
CFD. Lastly, to capture wind flow phenomena in sufficient detail, large finite volume models are 
necessary requiring significant processing power. These large models generate a great amount 
of data, which in turn needs to be stored and analyzed. 

There have been a few studies that use CFD in the built environment. He and Song, (1999) used a 
LES simulation CFD model based on the weakly compressible flow equations to simulate pedes-
trian fields around an urban area. Three case studies are presented showing differing wind effects. 
CFD is not however used as a design tool to modify proposed buildings nor is a wind tunnel test 
used to validate the results. A comparison of numerical results is presented with the classic wind 
tunnel tests on different buildings. 

Janssen, Blocken and Hooff (2013) compared different wind comfort criteria based on a case 
study of Eindhoven University, Netherlands. Validation was possible using real-world measure-
ments from the university, taken over a two-hour span. There was no modification proposed 
during a design process. In (Blocken Janssen and Hooff, 2012) a framework is presented for the 



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Journal of Sustainable Architecture and Civil Engineering 2017/2/19

integration of the existing best practice guidelines into wind comfort and wind safety studies per-
formed with CFD. The same Eindhoven University case study and validation is used to build the 
framework. Fadl and Karadelis (2013) undertook CFD simulation for wind comfort and safety at 
Coventry University, in the UK. No validation tests were conducted and no changes to the design 
were needed.

This paper proposes a world first, to validate CFD against wind tunnel tests for the same building 
while also proposing a change in design to alleviate pedestrian discomfort. The results showcased 
here were determined through a consultancy project by the team at Arup, Dublin. On determining 
potential wind problems, mitigation measures were proposed and tested in CFD to prove that the 
mitigation measures work. These proposed changes were incorporated into the final design and 
as a result planning permission was awarded for the development. This work is exemplar of how, 
from the very conception of the project design, new technological advances lead to a better built 
and sustainable environment for all.

The proposed development at the Dublin docklands consists of the construction of an office build-
ing ranging in height from 8 to 17 storeys, herein referred to as the Dublin Docklands tall building. 
The construction of new buildings and the alteration of the existing landscape may alter the flow of 
the wind in the surrounding area (Penwarden, 1973). It was found that the proposed development 
can generate a wind environment at ground level that is discomforting or even possibly dangerous 
to pedestrians, these metrics were determined in accordance with the Lawson Comfort Criteria 
(Lawson, 2001) previously discussed. This case study was first modelled in a wind tunnel test, 
where the potential for pedestrian discomfort was identified. Arup undertook the wind modelling 
of the entire built landscape using CFD to first validate and prove that the augmentation to the 
design taking into account these findings. The wind tunnel test and the CFD model are discussed 
in this section. An assessment of the microclimate was also undertaken to test the CFD model in 
historic wind conditions.

Wind Tunnel Test 
The objective of a wind tunnel test is to produce estimates of wind effects with specified mean 
recurrence intervals. Wind tunnel tests measure aerodynamic or aero-elastic data associated with 
wind-structure interaction, i.e. aerodynamic pressures, the dynamic or aero-elastic response and 
wind speeds affecting pedestrian spaces. The object or model under investigation is placed in the 
centre of the wind tunnel, sufficiently downstream to facilitate the development of the velocity 
profile, and sufficiently upstream to capture the wake of the flow. Air at a given velocity is blown 
down the tunnel using a fan. Small blocks or spike are used upstream of the model under investi-
gation to simulate turbulence in the flow. Sensors are distributed on the surface of the scale model 
placed in locations of interest.

A boundary layer wind tunnel study of the proposed development at the Dublin Docklands tall 
building was previously conducted by another company at a local wind tunnel facility to assess 
the impact of the proposed development on the wind microclimate. The study examined the 
wind microclimate of the Dublin Docklands in its existing configuration and the proposed de-
velopment.

CFD Modelling Methodology
Modelling in CFD comprises three main stages: pre-processing, simulation and post-process-
ing. Pre-processing involves the construction of the geometric model for the flow domain of in-
terest, and the subsequent division of this domain into small control volumes (cells), a process 
often called ‘meshing’. The flow field and the equations of motion are discretized, and the re-
sulting system of algebraic equations is solved to give values at each node. Once the model and 

Methodology



Journal of Sustainable Architecture and Civil Engineering 2017/2/19
96

the mesh have been created, appropriate initial conditions and boundary conditions are applied. 

The Navier-Stokes equations, the governing equations for the behaviour of fluid particles, are 
solved iteratively in each control volume within the computational domain until the solution con-
verges. The field solutions of pressure, velocity, air temperature and other properties can be cal-
culated for each control volume at cell centres and interpolated to out points in order to render 
the flow field. 

Post-processing involves graphing the results and viewing the predicted flow field in the CFD 
model at selected locations, surfaces or planes of interest. The Navier-Stokes equations, used 
within the CFD analysis, apply a numerical representation to approximate the laws of physics to 
produce extremely accurate results, providing the scenario modelled is representative of reality.

As part of the computational process, the domain was divided into a total of 16 million cells. The 

Fig. 1  
Computational 

Domain

Fig. 2
Wind Speeds – 

Comfort Criteria

Fig. 3
Wind Speeds – 

Distress Criteria

cells range in size from 0.4 m at the Dublin 
Docklands tall building to 3.2 m at the out-
er domain (Fig. 1). Closed boundary con-
ditions were applied on the bottom face 
of the domain, representing the ground. 
Open boundary conditions were modelled 
elsewhere.

As with any computer simulation, the qual-
ity of the results is dependent on the quality 
of the inputs; the assumptions, modelling 
characteristics employed and the equa-
tions used to represent the phenomena. 
There will inevitably be approximations, 
and a robust model validation process is 
essential. A high-level understanding of 
the modelling process and of the phenom-
ena being modelled is necessary for the 
output to be of any practical use. 

Assessment of the climate 
The local wind climate was determined 
from historical meteorological data re-
corded at Dublin Airport. Two different 
datasets were analysed, namely; the data 
associated with the maximum daily wind 
speeds recorded over a 30-year period 
between 1985 and 2015, and the mean 
hourly wind speeds recorded over a 10-
year period between 2005 and 2015. The 
wind speeds in the vicinity of the devel-
opment will differ from the wind recorded 
at Dublin Airport. It is necessary to trans-
form the wind speeds to take account of 
local conditions (Simiu, 2001). From this, 
a single wind speed profile was deter-
mined for each direction for both com-
fort and distress criteria, as illustrated in 
Fig. 2 and Fig. 3.



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Journal of Sustainable Architecture and Civil Engineering 2017/2/19

A verification of the model used in this research investigated the effects of five parameters; the up-
stream length, the downstream length, the model height, the cross-stream width and mesh size. 
In essence this captures the sensitivity of the results to the size and shape of the domain. Using 
a Modified Partial Design Technique adapted from (Box, 2005), nine models were created using 
variations in these parameters, the combinations of which are shown in Table 1.

Verification 
by Sensitivity 
Analysis

Table 1
Nine combinations 
for use in the Partial 
Design Technique

Model
Upstream Length (m) Downstream Length (m) Height (m) Cross-Stream Width (m)

- = 150    + = 250 - = 35    + = 245 - = 78    + = 128 - = 170    + = 415

1 - - - -

2 + - - +

3 - + - +

4 + + - -

5 - - + +

6 + - + -

7 - + + -

8 + + + +

9 200 140 103 293

The results of the nine models were analysed to assess sensitivity of the results of wind velocity 
to each of the four parameters. Fig. 4 shows the sensitivity of the recorded velocity at sensor lo-
cations H2, B2, E11 and E9. H2 is placed at the north-east corner of the building, B2 is placed on 
the north-west corner of the building, and sensors E11 and E9 are located in the undercroft. All 
sensors are at a height of 1.6m. 

From each of the sup plots of Fig. 4, it is observed that the same trend of sensitivities emerge as 
the upstream length, downstream length, height and cross-section width are altered. Examining 

Fig. 4
Verification of results 
from four sensors 
placed at grid reference 
points H2, E11, B2, 
and E9

 

  

 



Journal of Sustainable Architecture and Civil Engineering 2017/2/19
98

one of these plots, in the case of sensor location H2, as the upstream length increases, less than 
a 5% decrease in velocity is observed. It was found that the recorded velocities were also slightly 
sensitive to changes in downstream length. For sensor location H2 as the downstream length 
increases, the velocities range from 3.8 m/s to 4.25 m/s respectively. Less than a 5% increase is 
observed in the velocities of this sensor as the domain height increases. In relation to the effect of 
the cross-stream width on results, the velocities recorded at the twelve locations were found to be 
insensitive to changes in the cross-steam width. The trend seen in these velocities are replicated 
for eleven other sensors placed at various locations throughout the model. 

A tenth verification model was created to assess the sensitivity of velocity results to changes in mesh 
size. In this model, the domain size matches that of the 9th model, provided in the Table 1; however, the 
mesh size was half as fine (0.2 m as opposed to 0.4 m). Even with this increase in granularity the veloc-
ities observed by the twelve sensor locations were found to be insensitive to decreasing the mesh size. 

Validation

Fig. 5
CFD Data Sampling 

Locations at 
Pedestrian Level

Fig. 6
Data Sampling 

Locations at 
Pedestrian Level of 

the external company

 

  

To validate the CFD modelling process the environment was recreated in the wind tunnel analysis 
predetermined by the external company. For the purposes of validation of the models, the original 
Dublin Docklands tall building model was considered. The exterior of the building was considered to be 
smooth, which is consistent with the wind tunnel tests and therefore, it neglects any influence of the 
external truss on the flow. The equivalent average hourly gust speed is calculated based on 5% turbu-
lence intensity and a K value of 1.5. The data sampling locations (Fig. 5 and 6), have been selected to 
be as close as possible to the exact sensor locations used in the wind tunnel tests. This study focuses 
on Points 18 to 28 and is confined to comparing, at these locations, the CFD results with the findings 
of the previous microclimate study. The comfort criteria and distress criteria adopted in this study are 
consistent with the previous wind assessment carried out by the external company.

The validation results of the CFD simulation of the Dublin Docklands tall building shows good con-
sistency with the original wind tunnel test results. As indicated in Fig. 7 and 8, the CFD simulation 
results suggest that many of the same locations identified using wind tunnel testing suffer from 
pedestrian discomfort and distress. Therefore, the results of the CFD models are considered to be 
consistent with the original wind tunnel test results.

5 6



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Journal of Sustainable Architecture and Civil Engineering 2017/2/19

The assessment of the pedestrian comfort and distress in the pedestrian thoroughfare between the 
3Arena and the Dublin Docklands indicates that the main areas of concern are at the southern end. 
The equivalent wind speeds from the perspective of comfort and distress are 12 m/s and 24 m/s 
respectively. These speeds arise when high westerly winds cause discomfort and distress between 
the 3Arena and the Dublin Docklands tall building (Fig. 9). Midway along the building, the equivalent 
hourly average gust wind speed from a comfort perspective is 8.3 m/s. at the northern end, the 
analysis reveals that the wind speeds are insufficient to cause either discomfort or distress.

In addition, it is possible that winds from the south and north will be of distress to the public. The 
equivalent hourly average gust speed is estimated at 15.4 m/s and 16.3 m/s from the North and 
Southwest, respectively. These wind speeds exceed the distress threshold for the public of 15 m/s.

Fig. 7
Wind Tunnel Tests Wind 
Microclimate Results 
Summary for Original 
Dublin Docklands tall 
building with Mitigation 
Measures in Future 
Environment

Fig. 8
CFD Simulation Wind 
Microclimate Results 
Summary for Original 
Dublin Docklands tall 
building with Mitigation 
Measures in Future 
Environment

    

87

Fig. 9 
Distress Criteria, 
Wind from the West, 
Minimum values 
in blue (0m/s), 
Maximum values in 
red (20m/s)

Results

 



Journal of Sustainable Architecture and Civil Engineering 2017/2/19
100

  

 

  

 

  

 

The assessment of the pedestrian comfort and dis-
tress in the passageways between the Dublin Dock-
lands tall building reveals that the wind conditions 
might be discomforting and distressing to pedestrian. 
However, the level of discomfort and distress is relat-
ed to the wind direction. For instance, while westerly 
winds with an annual return period may produce con-
ditions unsuitable for undertaking any activity within 
the undercroft, a slight shift in direction to the south 
results in an acceptable environment. It would appear 
that much of the pedestrian discomfort and distress is 
due to westerly winds. From the perspective of com-
fort, the equivalent hourly average gust speed in the 
undercroft passageways range between 10 m/s and 
13.9 m/s for westerly winds, which is considered un-
comfortable irrespective of the activity being under-
taken. The main source of distress is due to westerly 
winds which range between 15 m/s and 30 m/s along 
the length of the building. These high wind speeds near 
ground level are due to the building funnelling high 
level winds downward. The wind speeds are further 
increased through the undercroft passageways as the 
wind is forced through narrower openings underneath 
the building (Fig. 10). Although it might be expected 
that easterly winds might cause similar pedestrian 
discomfort and distress within the building undercroft, 
it is apparent from Fig. 11 that this is not the case. The 
wall on the western boundary of Dublin Port acts to 
disturb the wind. The bluff nature of the wall causes 
the flow to separate and the formation of large vortex 
between the wall and the Dublin Docklands tall build-
ing (Fig. 12). The vortex acts to push much of the wind 
over the Dublin Docklands tall building. As a conse-
quence, there is less flow passing under the Dublin 
Docklands tall building. 

Fig. 12
Distress Criteria, Wind 

from the East, Minimum 
values in blue (0m/s), 

Maximum values in red 
(20m/s)

Fig. 11 
Distress Criteria, Wind 

from the East, Minimum 
values in blue (0m/s), 

Maximum values in red 
(20m/s)

Fig. 10 
Distress Criteria, Wind 

from the West, Minimum 
values in blue (0m/s), 

Maximum values in red 
(20m/s)



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Journal of Sustainable Architecture and Civil Engineering 2017/2/19

Modifications to the design
The assessment of the wind microclimate indicates that westerly winds are responsible for 
most of the pedestrian discomfort and distress associated with this development. Furthermore, 
the high-speed winds present at ground level are largely due to downdrafts. These high-speed 
winds are further exacerbated by the narrower openings between the cores within the under-
croft. It should be possible to improve the quality of the public realm near the Dublin Docklands 
tall building with respect to the wind microclimate by preventing these high-speed air flows in 
reaching the ground.

The downdraft can be mitigated through the provision of a canopy above ground level along the 
western edge the building. The design was modified to include a 3.0 m canopy. The purpose of this 
modification is to enable the canopy to act as a wind gutter. The extension of the canopy to the 
edges of the building helps the development of a positive pressure gradient along the canopy with 
the objective of driving the flow around the building rather than underneath it. The modifications 
to the canopy were considered in a further simulation. In addition, while the original CFD models 
utilised a relatively coarse mesh, which permitted a crude representation of the exterior truss 
in the model, this model adopted a finer mesh of moderate refinement, which enables the truss 
structure to be represented more accurately. 

The results of this simulation reveal that the ground level wind speeds are considerably lower than 
the earlier simulations beneath the building and along the pedestrian thoroughfare between the 
3Arena and the Dublin Docklands tall building. For instance, a significant decrease in wind speed 
was identified underneath the building near the northern core, where the equivalent hourly aver-
age gust speed reduced from 30 m/s to 14.5 m/s. This reduction in wind speed is attributed to the 
provision of a larger canopy.

It is apparent from Fig. 13 that the canopy does not confine the flow completely. However, it does 
indicate the presence of a large wake region below the canopy. This wake region does indicate that 
the canopy disrupts the downdraft. The overall effect is to reduce the velocity of the flow through 
the undercroft as illustrated in Fig. 14 and 15 with the effect of significantly improving pedestrian 
comfort to acceptable levels. Furthermore, the canopy proposed in the design is 3 m wide which 
enhances its effectiveness. This will further reduce the wind speeds within the undercroft and im-
prove pedestrian comfort to more acceptable levels.

Fig. 13
Comparison of 1.5 m 
canopy (left) and 2.5 m 
wind gutter (right) for 
Distress Criteria, Wind 
from West, Elevation View 
from the West, Minimum 
Values in Blue (0m/s), 
Maximum Values in Red 
(20m/s)

 



Journal of Sustainable Architecture and Civil Engineering 2017/2/19
102

This research has validated that CFD obtains equivalent results, comparable to and in agreement 
with a wind tunnel test. Further, as potential wind problems were uncovered in the design stage 
of a building submitting for planning permission, mitigation measures were proposed and tested 
in CFD to verify the proposed changes. These changes were incorporated into the final design and 
as a result planning permission was awarded for the development. This case study is exemplar 
of how, from the very conception of the project design, new technological advances lead to a 
better built and sustainable environment for all. This paper shows that CFD has a role to play in 
informing design to mitigate unpleasant wind conditions. In summary, CFD is a strand of applied 
research that has the potential to improve quality of design, is of immediate practical use and has 
a significant role to play in sustainable consulting engineering. 

Fig. 14  
Distress Criteria, Wind from 

West, Elevation View from 
the West, Minimum Values 
in Blue (0m/s), Maximum 

Values in Red (20m/s)

Fig. 15  
DistressCriteria, Wind 

from West, Elevation View 
from the North, Minimum 

Values in Blue (0m/s), 
Maximum Values in Red 

(20m/s)

 

  

 

14 15

Conclusions

Acknow-
ledgment

The authors wish to acknowledge the support 
of Arup Ireland in the completion of this work. 

Apperly, L.W. and Vickery, B.J. The prediction and 
evaluation of the ground level wind environment. In 
Proceedings of the Fifth Australasian Conference of 
Hydraulics and Fluid Mechanics, University of Can-
terbury, Christchurch, New Zealand, 1974.

Blocken, B., Janssen, W.D., van Hooff, T. CFD simu-
lation for pedestrian wind comfort and wind safety in 
urban areas: general decision framework and case 
study for the Eindhoven University Campus. Envi-
ronmental Modelling and Software, 2012; 30: 15-34. 
https://doi.org/10.1016/j.envsoft.2011.11.009

Box, G. E.; Hunter, W. G.; Hunter, J. S. (2005). Statis-
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Fadl, M.S. and Karadelis, J. CFD simulation for wind 
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Fachsbart, O. Wind pressure on closed and open 
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Isyumov, N. and Davenport, D.G. The ground level 
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About the 
authorsJENNIFER KEENAHAN

Assistant Professor1 and 
Project Engineer2 
1School of Civil Engineering, 
University College Dublin  and 
2Arup Dublin 

Main Research Area

Computational Fluid Dynamics 
for the Built Environment 

Address

50 Ringsend Road,  
Ringsend, Dublin 4. 
Tel. 01 2334455
E-mail: jennifer.keenahan@ucd.ie 

REAMONN MAC REAMOINN

Senior Engineer 

Arup Dublin 

Main Research Area

Computational Fluid Dynamics for 
the Built Environment 

Address

50 Ringsend Road,  
Ringsend, Dublin 4. 
Tel. 01 2334455
E-mail: reamonn.macreamoinn@
arup.com 

CRISTINA PADUANO

Senior Engineer 

Arup Dublin 

Main Research Area

Computational Fluid Dynamics for 
the Built Environment 

Address

50 Ringsend Road,  
Ringsend, Dublin 4. 
Tel. 01 2334455
E-mail: cristina.paduano@arup.com