49
Journal of Sustainable Architecture and Civil Engineering 2018/2/23

*Corresponding author: mantas.dobravalskis@ktu.lt

Potential of Harvesting 
Rainwater from 
Vertical Surfaces

Received  
2018/09/24

Accepted after  
revision 
2018/11/03

Journal of Sustainable 
Architecture and Civil Engineering
Vol. 2 / No. 23 / 2018
pp. 79-85
DOI 10.5755/j01.sace.23.2.21606 

Potential of 
Harvesting Rainwater 
from Vertical 
Surfaces

JSACE 2/23

http://dx.doi.org/10.5755/j01.sace.23.2.21606

Mantas Dobravalskis*, Paulius Spūdys, Juozas Vaičiūnas, Paris Fokaides 
Kaunas University of Technology, Faculty of Civil Engineering and Architecture  
Studentu st. 48, LT-51367 Kaunas, Lithuania

The water supply chain is under increasing stress as urbanisation and population growth is driving more 
and more people to move to cities. An increasing amount of city planners are now looking for alternative 
water resources, rainwater being one of them. There are multiple benefits to on-site water collection, 
storage and use, as proven by multiple published studies and successful projects around the world; 
however, rainwater harvesting (RWH) has remained a niche technique, not seen as part of the mainstream. 
One of the reasons for this is that, traditionally, rainwater has only been collected from rooves and other 
horizontal surfaces, and then transferred and stored in various subsurface holding tanks. This method of 
RWH is dated and not very effective. Furthermore, rainwater is one of the purest water sources, but when 
collected from horizontal surfaces, it gets polluted with particles that have settled on those surfaces. As a 
result, RWH in this way can be used only for specific purposes. In order to fully utilise this natural resource, 
to enable the creation of sustainable cities, we must devise a new method for collecting rainwater. One 
aspect of RWH that has not yet been deeply explored is collecting it from vertical surfaces. Although some 
abstract studies have already been conducted, concerning water runoff from vertical surfaces, no studies 
have evaluated the possibility of harvesting and using such water.
In this paper, the impacts of different sets of conditions and variables on the performance of RWH systems 
mounted on vertical surfaces, such as building facades, are compared. In addition, this study aimed to 
evaluate the potential of such systems to be used in real-world projects around the globe. To accurately 
measure collected rainwater, an experimental stand was constructed. This stand consisted of a mechanism 
that allowed the water-collecting surface and its parameters to be changed, whilst also measuring various 
aspects of the weather and the amount of water that was successfully harvested. The experiments were 
conducted in both a controlled environment (laboratory) and under real (natural) conditions.
The results of this study provide a more accurate evaluation of how vertical RWH systems can be 
implemented in real-life projects around the globe and show how natural conditions and the surfaces 
used can change the effectiveness of RWH.

Keywords: rainwater harvesting, sustainable cities, vertical surfaces, water source, wind driven rain.

Introduction
Under real-life conditions, all rain has a horizontal velocity due to wind acting upon rain droplets. 
Such rain is called wind-driven rain (WDR). Even though most building facades are completely 
vertical, rain still hits them due to this reason. This provides an opportunity for collecting such rain 
from vertical surfaces, allowing it to be used in water supply systems.

On the other hand, WDR is not only an opportunity, but also a threat. Multiple studies have showed 
that rainwater can do serious damage to building materials and their longevity (Abuku, Janssen, 
Roels, 2009; Blocken, Deromeb, Carmeliet, 2013). All porous construction materials can hold a 
maximum amount of moisture, but when this threshold is reached or exceeded, serious damage 



Journal of Sustainable Architecture and Civil Engineering 2018/2/23
50

can occur. Frost damage due to expanding water, the discolouration of facade materials and struc-
tural degradation are all caused by excess water in facades (Kyllingstad et al., 2010). 

There are multiple benefits to harvesting rainwater from building facades, for example cleaner 
surface and more unused space when compared to roofs. But there have not yet been meaningful 
or comprehensive studies in this field. Evaluating the WDR harvesting potential from vertical sur-
faces requires accurate RWH measurement datasets that follow guidelines to guarantee precise 
and reliable data. Such information would also be of use in future studies, and in the development 
of such wind-driven RWH systems for use in real buildings around the world.

This study aimed to precisely measure the amount of rainwater that could be successfully col-
lected from vertical surfaces, such as building facades. To that end, a specialized WDR harvesting 
stand was developed and manufactured. A first series of experiments was conducted in the lab-
oratory using simulated rain. The experimental stand had the ability to change the angle of the 
vertical surface by up to 7.5°. Both successfully harvested rainwater and runoff were measured. 
Load cells were used as primary parts of the measuring equipment. These can measure mass 
changes, as times goes by, and allowed us to observe how effective the system was, as well as 
how the rain intensity impacted the effectiveness of the system. In the Methods section, a detailed 
description of the experimental stand is given, alongside photos and drawings, as well as of the 
main control unit. This section also contains an explanation of the methodology that was used to 
analyze the data collected during the experiments. The Results section presents the parameters 
of the simulated rain, the measured RWH data and the results of the data analysis. These results 
show the percentages of rainwater that can be harvested, of water runoff and of rainwater that 
splashed off and could not be harvested. 

Methods

Fig. 1 
System used for wind 

driven rainwater 
harvesting from 
vertical surfaces  

(a -RWH assembly, 
b - base, c – main 

control unit, d – data 
logging process)

The experimental stand for measuring the rainwater collection rate was constructed. This is 
shown in Fig. 1, and is composed of two main parts – the RWH stand and the main control 
unit.

a)

b)

c)

d)



51
Journal of Sustainable Architecture and Civil Engineering 2018/2/23

Experimental stand
The experimental stand for RWH comprises of a RWH assembly(a) and a base(b) (Fig. 2). 

The main purpose of the base was to hold the water-measuring scales(c) and ensure stability of the 
RWH assembly. The base measured 1000 mm x 970 mm x 300 mm. Due to the stand comprising 
of two parts, the base had two sockets that enabled easy installation of the RWH assembly. Each 
side of the base was covered in aluminum sheeting and cement particleboard. This was required to 
make sure that the mass measuring equipment in the base would not be exposed to water droplets 
splashing from the vertical surface of the stand, or from other excess water that had not been har-
vested. Cement particleboard was used to increase the mass of the base, so that it was more stable 
and could be used outside in windy conditions in the study planned for natural outdoor conditions. 

Fig. 2 
Experimental stand 
(a - RWH assembly, 
b – base, c – water 
scales for harvested 
rainwater and runoff)

  
 

 
Fig 2. Experimental stand (a - RWH assembly, b – base, c – water scales for harvested rainwater and runoff) 

 
The RWH assembly imitates a real building facade, with a system for wind-driven RWH. This is illustrated in Figure 

2. It has additional equipment for transporting the harvested rainwater to measuring devices at the base. This part of the 
experimental stand was constructed from a hermetic box, with the front side covered with the facade panel being tested. The 
depth of the box was 58 mm. Water that permeated through the facade panel ran down the box and into a gutter that had an 
outlet hose running to Scale 1 – the scale that tracked the mass of harvested rainwater. Rainwater runoff that flowed down 
the panel surface and did not enter the box was collected by another gutter that was mounted on the outside of the box. 
Water from this gutter went to Scale 2, which measured rainwater runoff. A section of RWH assembly is shown in Figure 3. 

 
Fig 3. Wind driven rainwater harvesting system section also showing ways that rain droplets can act upon falling on the 

facade panel 
One architectural panel was tested – a type commonly used in modern architecture, which was supplied by a 

company that supplies metal facade panels for construction of various buildings. Using an existing panel proved that the 
suggested RWH system could be implemented in various types of buildings without limitations on the design or materials 
being used. The panel tested was made of expanded metal; its full parameters are shown in Table 1. 
 

The RWH assembly imitates a real build-
ing facade, with a system for wind-driven 
RWH. This is illustrated in Fig. 2. It has 
additional equipment for transporting 
the harvested rainwater to measuring 
devices at the base. This part of the ex-
perimental stand was constructed from a 
hermetic box, with the front side covered 
with the facade panel being tested. The 
depth of the box was 58 mm. Water that 
permeated through the facade panel ran 
down the box and into a gutter that had an 
outlet hose running to Scale 1 – the scale 
that tracked the mass of harvested rain-
water. Rainwater runoff that flowed down 
the panel surface and did not enter the 
box was collected by another gutter that 
was mounted on the outside of the box. 
Water from this gutter went to Scale 2, 
which measured rainwater runoff. A sec-
tion of RWH assembly is shown in Fig. 3.

Fig. 3
Wind driven rainwater 
harvesting system 
section also showing 
ways that rain 
droplets can act upon 
falling on the facade 
panel

a)

b)
c)

Water scales



Journal of Sustainable Architecture and Civil Engineering 2018/2/23
52

One architectural panel was tested – a 
type commonly used in modern archi-
tecture, which was supplied by a com-
pany that supplies metal facade panels 
for construction of various buildings. 
Using an existing panel proved that the 
suggested RWH system could be im-
plemented in various types of buildings 
without limitations on the design or ma-
terials being used. The panel tested was 
made of expanded metal; its full parame-
ters are shown in Table 1.

Water was sprayed though a fixed water 
hose nozzle that was fixed to a tripod so 
that it could be adjusted easily while still 
remaining stable when spraying water. 
All of the experiments where conducted 
with the water nozzle in the same posi-
tion. The water nozzle was connected to 

Table 1 
Parameters of 

facade panel 
being tested

Number. 3

Photo

 

  
 

Table 1. Parameters of facade panel being tested 
Number. 3 

Photo 

  

Holes scheme 

 
Hole measurements a = 100mm; b = 34mm 
Panel area, m2 1.0 
All holes area, m2 0.659 
Percentage of holes from all area, % 65.9 

 
Water was sprayed though a fixed water hose nozzle that was fixed to a tripod so that it could be adjusted easily 

while still remaining stable when spraying water. All of the experiments where conducted with the water nozzle in the same 
position. The water nozzle was connected to the city water supply by a hose. The nozzle valve was set to one position, and 
kept the same for all experiments. Only the main water supply valve was closed and opened during the experiments. 

For the water storage, two plastic boxes were used. Each of these could hold up to 40 l of water. A special pipe 
fitting was fixed at the top of the box to allow water from the gutters to flow into it. At the base of each box, a metal end cap 
was fitted for easy and fast emptying of the boxes. 

 
Main control unit 
The main control unit was constructed from off-the-shelf components. Arduino was selected as the main controller of 

the system that all other components were connected to. A layout of main control unit components is shown in Figure 4.  
The system used two separate scales – Scale 1 to measure the weight of the rainwater that was successfully harvested during 
the experiment, and Scale 2 that measured the runoff water from the RWH surface (facade panel). 

 
Fig 4. Main control unit schematic 

Both scales had identical construction and components. As the base for the scale, modular metal brackets were used 
that were put together using rivets.  The main parts of the scales were the load cells. Due to their wide availability and high 
accuracy, strain-gauge-type load cells were selected. Each cell had a maximum capacity of 10 kg. In order to achieve the 
required scale capacity, multiple load cells were used per scale. In order to accurately read the changes in the electrical 
signals generated by the deforming load cell, specialized HX711 amplifiers were used. The amplified signal was measured 
by the Arduino microcontroller, and then was interpreted as mass. The technical specifications of the load cells used are 
shown in Table 2. 

 
Table 2. Technical specifications of load cells that are used in scales 

Capacity kg 10 

Holes scheme

  
 

Table 1. Parameters of facade panel being tested 
Number. 3 

Photo 

  

Holes scheme 

 
Hole measurements a = 100mm; b = 34mm 
Panel area, m2 1.0 
All holes area, m2 0.659 
Percentage of holes from all area, % 65.9 

 
Water was sprayed though a fixed water hose nozzle that was fixed to a tripod so that it could be adjusted easily 

while still remaining stable when spraying water. All of the experiments where conducted with the water nozzle in the same 
position. The water nozzle was connected to the city water supply by a hose. The nozzle valve was set to one position, and 
kept the same for all experiments. Only the main water supply valve was closed and opened during the experiments. 

For the water storage, two plastic boxes were used. Each of these could hold up to 40 l of water. A special pipe 
fitting was fixed at the top of the box to allow water from the gutters to flow into it. At the base of each box, a metal end cap 
was fitted for easy and fast emptying of the boxes. 

 
Main control unit 
The main control unit was constructed from off-the-shelf components. Arduino was selected as the main controller of 

the system that all other components were connected to. A layout of main control unit components is shown in Figure 4.  
The system used two separate scales – Scale 1 to measure the weight of the rainwater that was successfully harvested during 
the experiment, and Scale 2 that measured the runoff water from the RWH surface (facade panel). 

 
Fig 4. Main control unit schematic 

Both scales had identical construction and components. As the base for the scale, modular metal brackets were used 
that were put together using rivets.  The main parts of the scales were the load cells. Due to their wide availability and high 
accuracy, strain-gauge-type load cells were selected. Each cell had a maximum capacity of 10 kg. In order to achieve the 
required scale capacity, multiple load cells were used per scale. In order to accurately read the changes in the electrical 
signals generated by the deforming load cell, specialized HX711 amplifiers were used. The amplified signal was measured 
by the Arduino microcontroller, and then was interpreted as mass. The technical specifications of the load cells used are 
shown in Table 2. 

 
Table 2. Technical specifications of load cells that are used in scales 

Capacity kg 10 

Hole measurements a = 100mm; b = 34mm

Panel area, m2 1.0

All holes area, m2 0.659

Percentage of holes 
from all area, %

65.9

the city water supply by a hose. The nozzle valve was set to one position, and kept the same for all 
experiments. Only the main water supply valve was closed and opened during the experiments.

For the water storage, two plastic boxes were used. Each of these could hold up to 40 l of water. A 
special pipe fitting was fixed at the top of the box to allow water from the gutters to flow into it. At 
the base of each box, a metal end cap was fitted for easy and fast emptying of the boxes.

Main control unit
The main control unit was constructed from off-the-shelf components. Arduino was selected as 
the main controller of the system that all other components were connected to. A layout of main 
control unit components is shown in Fig. 4.  The system used two separate scales – Scale 1 to 
measure the weight of the rainwater that was successfully harvested during the experiment, and 
Scale 2 that measured the runoff water from the RWH surface (facade panel).

Both scales had identical construction and components. As the base for the scale, modular metal 
brackets were used that were put together using rivets.  The main parts of the scales were the 
load cells. Due to their wide availability and high accuracy, strain-gauge-type load cells were se-
lected. Each cell had a maximum capacity of 10 kg. In order to achieve the required scale capacity, 
multiple load cells were used per scale. In order to accurately read the changes in the electrical 

Fig. 4 
Main control unit 

schematic

  
 

Table 1. Parameters of facade panel being tested 
Number. 3 

Photo 

  

Holes scheme 

 
Hole measurements a = 100mm; b = 34mm 
Panel area, m2 1.0 
All holes area, m2 0.659 
Percentage of holes from all area, % 65.9 

 
Water was sprayed though a fixed water hose nozzle that was fixed to a tripod so that it could be adjusted easily 

while still remaining stable when spraying water. All of the experiments where conducted with the water nozzle in the same 
position. The water nozzle was connected to the city water supply by a hose. The nozzle valve was set to one position, and 
kept the same for all experiments. Only the main water supply valve was closed and opened during the experiments. 

For the water storage, two plastic boxes were used. Each of these could hold up to 40 l of water. A special pipe 
fitting was fixed at the top of the box to allow water from the gutters to flow into it. At the base of each box, a metal end cap 
was fitted for easy and fast emptying of the boxes. 

 
Main control unit 
The main control unit was constructed from off-the-shelf components. Arduino was selected as the main controller of 

the system that all other components were connected to. A layout of main control unit components is shown in Figure 4.  
The system used two separate scales – Scale 1 to measure the weight of the rainwater that was successfully harvested during 
the experiment, and Scale 2 that measured the runoff water from the RWH surface (facade panel). 

 
Fig 4. Main control unit schematic 

Both scales had identical construction and components. As the base for the scale, modular metal brackets were used 
that were put together using rivets.  The main parts of the scales were the load cells. Due to their wide availability and high 
accuracy, strain-gauge-type load cells were selected. Each cell had a maximum capacity of 10 kg. In order to achieve the 
required scale capacity, multiple load cells were used per scale. In order to accurately read the changes in the electrical 
signals generated by the deforming load cell, specialized HX711 amplifiers were used. The amplified signal was measured 
by the Arduino microcontroller, and then was interpreted as mass. The technical specifications of the load cells used are 
shown in Table 2. 

 
Table 2. Technical specifications of load cells that are used in scales 

Capacity kg 10 

signals generated by the deforming load 
cell, specialized HX711 amplifiers were 
used. The amplified signal was mea-
sured by the Arduino microcontroller, 
and then was interpreted as mass. The 
technical specifications of the load cells 
used are shown in Table 2.

All load cells are similar but have minor 
differences due to the manufacturing 
process. In order to accurately measure 
weight, all of the load cells needed to be 
calibrated, which was done by special 



53
Journal of Sustainable Architecture and Civil Engineering 2018/2/23

Table 2
Technical 
specifications of 
load cells that are 
used in scales

Capacity kg 10

Safe overload %FS 120

Ultimate overload %FS 150

Combined error %FS ±0.05

Non-linearity %FS ±0.05

Repeatability %FS ±0.03

Creep %FS/3min ±0.05

Operating temperature range °C -10 - +55

code. This code allowed a calibration factor to be set for each load cell individually. Tests were 
performed using known-mass objects to test the accuracy of each scale. The primary results 
showed inaccuracies of up to 2%. 

All the data processing and collecting was performed by an Arduino Mega board, which is an 
open-source development board that allows the combination and use of different kinds of sensors 
and devices. All the load cell outputs were connected to Arduino after passing through amplifiers. 
The resistance readings of the load cells were then interpreted as mass values. As there were 
multiple load cells per scale, several values were added to get a complete reading from each 
scale. A safety mechanism was also implemented to warn the user when the scales were close 
to being overloaded, as overloading load cells makes them deform past their plasticity, making 
further measurements unacceptable.

Data from the scales needed to be transferred to a computer for further analysis. A serial port con-
nection was established between a computer and the microcontroller using Arduino Ide software. 
To make the data easy to work with, and to perform the required calculations, it was transferred in 
real time straight into Microsoft Excel. This was done by using specialized software called PLX-DAQ. 
Mass and accurate times were tracked. The main control unit also had an SD card slot implemented. 
This was used as a backup, so that even if the computer was not functioning, all of the information 
would still be stored on the SD card and could later be imported to the computer. To accurately track 
time, it was collected from a real-time clock (RTC). Thanks to having the exact time attached to the 
data being collected, the data was very easy to work with and analyze later. This functionality will be 
very helpful in experiments conducted under real (natural) conditions. This will allow data gathered 
by our experimental stand to be easily compared with weather station data.

For the laboratory experiments, manual water emptying was used. For experiments conducted 
outside, Arduino was also connected to relays that would control the water management system 
that empties the water tanks automatically once they were full, or when it stopped raining. This 
made this system fully automated – a good solution for long-term experiments under real (nat-
ural) conditions.

Experiment description
All experiments in the first phase of the study were conducted in the laboratory, under the same 
conditions. No wind was used during the experiments, but angle of the water flow hitting the pan-
el was set so it simulates winds effects on rain. The experimental stand was mounted in place. 
The water nozzle stand was placed 95 cm from the facade panel. The angle of the water droplets 
hitting the facade panel were calculated to be between 50° and 65°. Because of the type of water 
nozzle used, different areas of droplets were hitting the facade at different angles (Fig. 5). The wa-
ter supply was set to one position, and all of the tests experienced the same intensity of simulated 
rain. The rain pattern hitting the facade panel can be seen in Fig. 5. The area of rain spatter was 



Journal of Sustainable Architecture and Civil Engineering 2018/2/23
54

approximately Sw = 0.76 m
2. SD = 0.24 m

2 was the area that was not hit by any of the water during 
the experiments. The nozzle was set in this way to make sure that 100% of the water sprayed hit 
the facade. This way, the amount of water that splashed off the facade, and so did not end up in in 
the RWH system, could be calculated.

Firstly, experiments using fully vertical surfaces were conducted. Four experiments, lasting from 1:00 
to 3:30 minutes, were conducted. After each experiment, the water tanks were manually emptied, 
then everything was reset to the starting position, and the next experiment was conducted. This was 
done with all the panels. Two more experiments were conducted with the experimental stand set at 
an angle. The first angle tested was 2.5°, and then 7.5°. All data from the tests were transferred, in 
real time, from the main control unit to a computer, and saved in Microsoft Excel. Data was collected 
each second. After all the data was collected, it was used to analyze the effectiveness of the system.

Data analysis
The experimental stand collected and measured three components of the rainwater (Fig. 3) – har-
vested rainwater (Qharv.), water runoff (Qrunoff) and water that had splashed off the facade panel (QSplash). 
The amount of water that had splashed off was calculated by subtracting the harvested rainwater and 
runoff water mass from the total water amount that was sprayed on to the experimental stand. The 
total water mass that was sprayed on to the facade was calculated by performing an additional test on 
the spray nozzle. For a measured amount of time, water was sprayed into a bucket, then the amount 
of water that was collected during that time period was measured. Chronometer and one of the scales 
from the experimental stand were used for these measurements. Calculations were then made to 
determine the mass of water that was sprayed on to the RWH experimental stand in 1 second. To find 
out the total water quantity sprayed during each test, a multiplication of the test duration and the rain 
intensity was made. With this information, all further calculations that were needed to evaluate the ef-
fectiveness of this RWH system could be made. The main results we were looking for were the amount 
of water that was harvested, runoff or splashed. All of these components of the RWH were calculated in 
both quantity in liters and as a percentage of all water that was sprayed on to the surface.

Fig. 5 
a) Water hitting 

panel pattern;  
b) Water droplets 

hitting facade 
panel angles

  
 

 
Fig 5 a) Water hitting panel pattern; b) Water droplets hitting facade panel angles 

 
Firstly, experiments using fully vertical surfaces were conducted. Four experiments, lasting from 1:00 to 3:30 

minutes, were conducted. After each experiment, the water tanks were manually emptied, then everything was reset to the 
starting position, and the next experiment was conducted. This was done with all the panels. Two more experiments were 
conducted with the experimental stand set at an angle. The first angle tested was 2.5°, and then 7.5°. All data from the tests 
were transferred, in real time, from the main control unit to a computer, and saved in Microsoft Excel. Data was collected 
each second. After all the data was collected, it was used to analyze the effectiveness of the system. 

 
Data analysis 
The experimental stand collected and measured three components of the rainwater (Fig. 3) – harvested rainwater 

(Qharv.), water runoff (Qrunoff) and water that had splashed off the facade panel (QSplash). The amount of water that had 
splashed off was calculated by subtracting the harvested rainwater and runoff water mass from the total water amount that 
was sprayed on to the experimental stand. The total water mass that was sprayed on to the facade was calculated by 
performing an additional test on the spray nozzle. For a measured amount of time, water was sprayed into a bucket, then the 
amount of water that was collected during that time period was measured. Chronometer and one of the scales from the 
experimental stand were used for these measurements. Calculations were then made to determine the mass of water that was 
sprayed on to the RWH experimental stand in 1 second. To find out the total water quantity sprayed during each test, a 
multiplication of the test duration and the rain intensity was made. With this information, all further calculations that were 
needed to evaluate the effectiveness of this RWH system could be made. The main results we were looking for were the 
amount of water that was harvested, runoff or splashed. All of these components of the RWH were calculated in both 
quantity in liters and as a percentage of all water that was sprayed on to the surface. 

a) b)

Results
During the experiments, the harvested and runoff rainwater were constantly monitored. The results 
showed stability and linear growth, as plotted in Fig. 6. All four experiments showed similar water 
mass growth rate with on average only 3% difference between all the experiments, so it can be 
concluded that the data was collected accurately, and no errors occurred during the experiments.



55
Journal of Sustainable Architecture and Civil Engineering 2018/2/23

Data was collected from the moment the water supply valve was opened to the moment it was 
closed. Due to air in the system, and the consequent unstable water flow at the beginning and end 
of the experiments, data that were not stable were removed from datasets. The amount of data 
deleted depended on each experiment. Only data with stable rainwater mass growth were used.

The simulated rain intensity was calculated using the method described above. After spraying all 
of the water into a bucket for 7.68 seconds, 870 g of water had been collected.  This amount of 
water was chosen because of limitation of our water tank used for measuring it. This experiment 
showed that the water nozzle sprayed 0.113 kg of water each second. This equal to 0.14mm/
(s*m2) rain intensity. Such rain is classified as very violent rain and is an extreme case. In nature 
such rain intensity only happens for very short spans of time.

Expanded stainless steel facade panel results
The expanded metal facade panel was perforated, with 66% of the area comprising perfora-
tions. Calculations were made based on both the full dataset and for random, short time periods 

Fig. 6 
Amount of water 
harvested during 4 
experiments that were 
conducted in this study 
(Facade panel vertical)

  
 

Results 
During the experiments, the harvested and runoff rainwater were constantly monitored. The results showed stability 

and linear growth, as plotted in Figure 6. All four experiments showed similar water mass growth rate with on average only 
3% difference between all the experiments, so it can be concluded that the data was collected accurately, and no errors 
occurred during the experiments. 

 

 
Fig 6. Amount of water harvested during 4 experiments that were conducted in this study (Facade panel vertical) 
 
Data was collected from the moment the water supply valve was opened to the moment it was closed. Due to air in 

the system, and the consequent unstable water flow at the beginning and end of the experiments, data that were not stable 
were removed from datasets. The amount of data deleted depended on each experiment. Only data with stable rainwater 
mass growth were used. 

The simulated rain intensity was calculated using the method described above. After spraying all of the water into a 
bucket for 7.68 seconds, 870 g of water had been collected.  This amount of water was chosen because of limitation of our 
water tank used for measuring it. This experiment showed that the water nozzle sprayed 0.113 kg of water each second. This 
equal to 0.14mm/(s*m2) rain intensity. Such rain is classified as very violent rain and is an extreme case. In nature such rain 
intensity only happens for very short spans of time. 

 
Expanded stainless steel facade panel results 
The expanded metal facade panel was perforated, with 66% of the area comprising perforations. Calculations were 

made based on both the full dataset and for random, short time periods during the test. These were compared in order to 
ensure that the results were accurate and stable throughout the duration of the experiments. The main results are listed in 
Table 3. 

 
Table 3. Results when facade panel is vertical  

Duration of experiment (s): 141 
Rainwater harvested (Qharv.): 66.44% 
Rainwater runoff (Qrunoff): 20.96% 
All rainwater sprayed (Qrain): 100% 
Harvested rainwater + runoff (Qharv.+Qrunoff): 87.40% 
Splashed off rainwater (Qsplash): 12.60% 

 
As we can see from the Table 3, results show that 66.44% of all rainwater that hit the facade was successfully 

harvested when panel was vertical. 20.96% of all rainwater can also be potentially harvested by using external gutter that 
collects runoff water from the facade. Finally, less than 13% of all rainwater was not harvested and have splashed of the 
facade panel past the external gutter that is collecting facade runoff water. 

Table 3
Results when 
facade panel is 
vertical 

Duration of experiment (s): 141

Rainwater harvested (Qharv.): 66.44%

Rainwater runoff (Qrunoff): 20.96%

All rainwater sprayed (Qrain): 100%

Harvested rainwater + runoff (Qharv.+Qrunoff): 87.40%

Splashed off rainwater (Qsplash): 12.60%

during the test. These were compared in order to ensure that the results were accurate and stable 
throughout the duration of the experiments. The main results are listed in Table 3.

As we can see from the Table 3, results show that 66.44% of all rainwater that hit the facade was 
successfully harvested when panel was vertical. 20.96% of all rainwater can also be potentially 
harvested by using external gutter that collects runoff water from the facade. Finally, less than 
13% of all rainwater was not harvested and have splashed of the facade panel past the external 
gutter that is collecting facade runoff water.

Angles impact on effectiveness 
of vertical rainwater harvesting 
system
Additional experiments were con-
ducted to analyze the impact of the 
angle of the facade on the effective-
ness of the RWH system. Two addi-
tional angles were tested – 2.5° and 



Journal of Sustainable Architecture and Civil Engineering 2018/2/23
56

7.5°. Both angles were tested once. The period of these experiments was 2:30 minutes for each 
angle. No other parameters were changed, either in the experimental stand or the methodology. The 
results are compared in Table 4. As can be seen from Fig. 7, by increasing the angle, the percentage 
of harvested water also grew. This proved that the facade angle could have a significant impact on 
the effectiveness of such a system, even though completely vertical facades collects up to 87% of 
all rainwater. 

Table 4 
Angles impact on 

effectiveness on 
RWH system

2.5°

Duration of experiment (s): 168

Rainwater harvested(Qharv.): 71.58%

Rainwater runoff(Qrunoff): 20.88%

All rainwater sprayed(Qrain): 100%

Harvested rainwater + runoff(Qharv.+Qrunoff): 92.44%

Splashed off rainwater(Qsplash): 7.54%

7.5°

Duration of experiment (s): 147

Rainwater harvested(Qharv.): 79.72%

Rainwater runoff(Qrunoff): 14.98%

All rainwater sprayed(Qrain): 100%

Harvested rainwater + runoff(Qharv.+Qrunoff): 94.70%

Splashed off rainwater(Qsplash): 5.30%

Fig. 7
 Comparison of 
different facade 

angles

  
 

 
Angles impact on effectiveness of vertical rainwater harvesting system 
Additional experiments were conducted to analyze the impact of the angle of the facade on the effectiveness of the 

RWH system. Two additional angles were tested – 2.5° and 7.5°. Both angles were tested once. The period of these 
experiments was 2:30 minutes for each angle. No other parameters were changed, either in the experimental stand or the 
methodology. The results are compared in Table 4. As can be seen from Figure 7, by increasing the angle, the percentage of 
harvested water also grew. This proved that the facade angle could have a significant impact on the effectiveness of such a 
system, even though completely vertical facades collects up to 87% of all rainwater.  

 
Table 4. Angles impact on effectiveness on RWH system 

 

2.5° 

Duration of experiment (s): 168 
Rainwater harvested(Qharv.): 71.58% 

Rainwater runoff(Qrunoff): 20.88% 

All rainwater sprayed(Qrain): 100% 

Harvested rainwater + runoff(Qharv.+Qrunoff): 92.44% 
Splashed off rainwater(Qsplash): 7.54% 

7.5° 

Duration of experiment (s): 147 
Rainwater harvested(Qharv.): 79.72% 

Rainwater runoff(Qrunoff): 14.98% 

All rainwater sprayed(Qrain): 100% 

Harvested rainwater + runoff(Qharv.+Qrunoff): 94.70% 
Splashed off rainwater(Qsplash): 5.30% 

 
 

 
 

Fig 7. Comparison of different facade angles 
 

  
 

 
Angles impact on effectiveness of vertical rainwater harvesting system 
Additional experiments were conducted to analyze the impact of the angle of the facade on the effectiveness of the 

RWH system. Two additional angles were tested – 2.5° and 7.5°. Both angles were tested once. The period of these 
experiments was 2:30 minutes for each angle. No other parameters were changed, either in the experimental stand or the 
methodology. The results are compared in Table 4. As can be seen from Figure 7, by increasing the angle, the percentage of 
harvested water also grew. This proved that the facade angle could have a significant impact on the effectiveness of such a 
system, even though completely vertical facades collects up to 87% of all rainwater.  

 
Table 4. Angles impact on effectiveness on RWH system 

 

2.5° 

Duration of experiment (s): 168 
Rainwater harvested(Qharv.): 71.58% 

Rainwater runoff(Qrunoff): 20.88% 

All rainwater sprayed(Qrain): 100% 

Harvested rainwater + runoff(Qharv.+Qrunoff): 92.44% 
Splashed off rainwater(Qsplash): 7.54% 

7.5° 

Duration of experiment (s): 147 
Rainwater harvested(Qharv.): 79.72% 

Rainwater runoff(Qrunoff): 14.98% 

All rainwater sprayed(Qrain): 100% 

Harvested rainwater + runoff(Qharv.+Qrunoff): 94.70% 
Splashed off rainwater(Qsplash): 5.30% 

 
 

 
 

Fig 7. Comparison of different facade angles 
 



57
Journal of Sustainable Architecture and Civil Engineering 2018/2/23

Although accurate data was collected and analysed, further studies are needed that will analyse 
how such a system will work under real (natural) conditions. This study only tested the situation 
where water droplets were hitting a facade panel with no horizontal angle, only vertical angle was 
used to simulate winds effect. Under real conditions, a building’s facade angle is rarely perpendic-
ular to the angle of the wind. This might have a significant impact on the effectiveness of this sys-
tem, as more droplets need to hit the surface of the panel, rather than going straight through the 
perforations. Furthermore, our simulated rain intensity was very high and rarely occurs in nature. 
Additional experiments with lower rain intensity are required to evaluate if it has any significant 
impact on the effectiveness of the RWH system.

No tests have yet been performed using wind. Wind has a big impact on the speed and angle of the 
droplets. According to literature our experiments used an angle close to the one that occurs under 
real conditions during very windy rain. In order to fully analyse such a system, studies to evaluate 
the wind impact are also needed. Consequently, experiments with variable winds are needed, as 
well as tests that evaluate how wind gusts impact the amount of rainwater that is harvested.

Rain is highly dynamic, with a lot of variables, many of which could have a significant impact on the 
suggested vertical RWH system, so a lot of work is still left to do to fully evaluate such systems.

Discussion

Conclusions

Acknow-
ledgment

Based on data analysis conducted after all the experiments, the following main conclusions can 
be made:

 _ Wind driven rain harvesting system mounted on vertical facades can collect up to 66% off all 
rainwater that hits the panel when water flow is 0.113 l/s and water droplets hit the panel 
between 50° and 65°

 _ When rain droplets hit the panel between 50° and 65° with 0.113 l/s water flow, up to 21% 
of water runoffs the facade panel surface and can still be collected using external gutters 

 _ Only 12.6% of water on average splashes off the facade and can’t be harvested when it hits 
the panel between 50° and 65° with water flow of 0.113 l/s

 _ Increasing angle of the facade panels also increases the effectiveness of the RWH system. 
When facade panels were angled at 7.5° systems effectiveness reached 80%.

The authors are indebted to UAB “Morionis” for the supply of architectural panels that were em-
ployed for the purpose of this study.

The authors are also thankful to UAB “Šilnuta” for the supply of materials for the construction of 
the experimental stand’s frame.

References
A. Kubilay, D. Derome, B. Blocken, J. Carmeliet, 
Wind-driven rain on two parallel wide buildings: 
Field measurements and CFD simulations. Journal 
of Wind Engineering and Industrial Aerodynamics, 
2015; Volume 146: 11-28. https://doi.org/10.1016/j.
jweia.2015.07.006

B. Blocken, D. Derome, J. Carmeliet. Rainwater run-
off from building facades: A review. Building and En-
vironment, 2013; Volume 60: 339-361. https://doi.
org/10.1016/j.buildenv.2012.10.008

B. Blocken, J. Carmeliet. A review of wind-driv-
en rain research in building science. Journal of 

Wind Engineering and Industrial Aerodynamics, 
2004; Volume 92, Issue 13: 1079-1130. https://doi.
org/10.1016/j.jweia.2004.06.003

Kyllingstad, S. Thiis, T. Flø, A. Potac.). Climate, envi-
ronment and frost damage of architectural heritage. 
2010; 10.1201/b10428-233.

M. Abuku, H. Janssen, S. Roels, Impact of wind-driv-
en rain on historic brick wall buildings in a moderately 
cold and humid climate: Numerical analyses of mould 
growth risk, indoor climate and energy consumption. 
Energy and Buildings, 2009; Volume 41, Issue 1: 101-
110. https://doi.org/10.1016/j.enbuild.2008.07.011



Journal of Sustainable Architecture and Civil Engineering 2018/2/23
58

S. Angrill, A. Petit-Boix, T. Morales-Pinzón, A. Josa, 
J. Rieradevall, X. Gabarrell. Urban rainwater runoff 
quantity and quality – A potential endogenous re-
source in cities?. Journal of Environmental Man-
agement, 2017; Volume 189: 14-21. https://doi.
org/10.1016/j.jenvman.2016.12.027

PARIS  
FOKAIDES 

Chief Researcher

Kaunas University of 
Technology, Faculty of 
Civil and Environmental 
Engineering

Main research area

Sustainable Energy in 
the Built Environment

Address

Studentu st. 48, 
LT-51367 Kaunas, 
Lithuania
Tel. +35799793207
E-mail:  
paris.fokaides@ktu.lt

Villarreal, Edgar & Dixon, Andrew. Analysis of A 
Rainwater Collection System for Domestic Water 
Supply in Ringdansen, Norrkoping, Sweden. Build-
ing and Environment, 2005; 40: 1174-1184. https://
doi.org/10.1016/j.buildenv.2004.10.018

MANTAS 
DOBRAVALSKIS

Student

Kaunas University of 
Technology, Faculty of 
Civil Engineering and 
Architecture

Main research area 

Rain water harvesting, 
water resources, 
sustainable 
development

Address 

Studentu st. 48, 
LT-51367 Kaunas, 
Lithuania 
Tel. +37060366536 
E-mail: mantas.
dobravalskis@ktu.lt 

PAULIUS  
SPŪDYS

Student

Kaunas University of 
Technology, Faculty of 
Civil Engineering and 
Architecture

Main research area 

Rain water harvesting, 
water resources, HVAC 
systems

Address 

Studentu st. 48, 
LT-51367 Kaunas, 
Lithuania 
Tel. +37063665869
E-mail:  
p.spudys@gmail.com 

JUOZAS 
VAIČIŪNAS

Lecturer

Kaunas University 
of Technology, 
Department of 
Civil Engineering 
and Architecture 
competences center

Main research area

Water resources, water 
supply and disposal 
systems, hydronic 
performance of HVAC 
systems, renewable 
energy, structural 
stability of buildings.

Address

Studentu st. 48, 
LT-51367 Kaunas, 
Lithuania
Tel. +37061556760
E-mail: juozas.
vaiciunas@ktu.lt

About the 
Authors