Air Wells, Dew Ponds & Fog Fences Database

 

**[rexresearch.com](http://rexresearch.com/)  
[rexresearch1.com](http://rexresearch1.com/)**


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**Air Wells, Fog Fences****,
& Dew Ponds**  
**Articles & Patents**

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******[NELSON, Robert : Air Wells, Dew
Ponds, & Fog Fences](NelsonAirwells/NelsonAirwells.htm)************[AUGUSTIN, Stephen : WaterCone](AugustinWaterCone/AugustinWatercone.htm)**  
[BRODAY,
David / FRIEDLER, Eric : Technion Air Well](BrodayTechnionAW/BrodayTechnionAW.html)  
  
[CHATTRE, Sheerang : Fog Collector](ChhatreFogCollector/ChhatreFogCollector.htm)****  
  
[**COHEN,
R. : Qinetiq Dew Collector**](#Qinetiq) ****[Dew Ponds](DewPond/DewPond.htm)****  
[****ESTEVES, Catarina : Fog
Collector****](EstevesFog/EstevesFog.htm)[**ELLSWORTH,
Michael, et al. : A2WH Atmospheric Water Generator**](EllsworthAW/EllsworthAW.htm)**[DIAZ-MARIN,
Carlos, et al. : Hydrogel Airwell](DiazMarinHydrogel/D%C3%ADazMarinHydrogel.html)**  
****[HENG, et al. : Fog
Collector](HengFogColl/HengFogColl.htm)******[HOFF, Petrus :
WaterBoxx](HoffWaterbox/HoffWaterBoxx.htm)  
  
[JAGTOYEN, Marit : Auto Exhaust Water
Recovery System](#Jagtoyen)  
  
[KLAPHAKE,
Wolf : Air Well](KlaphakeAW/KlaphakeAirWells.html)  
  
[KOHAVI, Ayre : Water-Gen Air Well](#Kohavi)** ******[McKINLEY, Gareth, et al. : Fog
Fence](McKinleyFogFence/McKinleyFogFence.html)** ****[OLMO, et al. : Fog Collector](OlmoGilFogColl/OlmoGilFog.html)********  
**[PARENT, Marc: Air Well](ParentAW/ParentAW.htm)  
  
[RETEZAR, Kristof : Fontus Air Well](RetezarFontusAW/RetezarFontusAW.html)  
  
[RICHARDS : AquaMagic Water Generator](RichardsAquamagic/RichardsAquamagic.html)  
  
[SHER, Abraham :
Air Well](SherAW/SherAW.html)** **[THEILOW,
Frank : Air Well](TheilowAW/TheilowAW.htm)   
  
[VITTORI,
Arturo : WarkaWater Air Well](VittoriWarkaAW/VittoriWarkaAW.htm)  
  
[WHISSON,
Maxwell : Max-Air Well](WhissonAirWell/WhissonAirWell.htm)  
  
[YAGHI,
Omar, et al. : MOF Air Well](YaghiAirWell/YaghiAirWell.html)******[ZHAO, Xuanhe, et al.: Atmospheric Water
Harvesting Window](ZhaoAtmosWaterHarvestWindow/ZhaoAtmosWaterHarvestWindow.html)**  
  
[Articles](#Articles)  
  
 [Patents](#Patents)**


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![](AWHMethods.jpg)

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![](AirWelld2ra07733g-ga.jpg)

  


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[**https://www.bestproductsreviews.com/water-from-air-machine**](https://www.bestproductsreviews.com/water-from-air-machine?targetid=kwd-296966478706&matchtype=b&device=c&campaignid=22102131339&creative=728527424818&adgroupid=181750570948&feeditemid=&loc_physical_ms=9194074&loc_interest_ms=&network=s&devicemodel=&placement=&keyword=$water%20from%20air%20machine&target=&aceid=&adposition=&trackid=us_all_top_2025&mId=407-132-4411&gad_source=5&gad_campaignid=22102131339&gclid=EAIaIQobChMIqq7zibKfkAMVXjatBh3MsTN1EAAYASAAEgI-9vD_BwE)**10 Best water from air machines of 2025**

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<http://www.sciencedirect.com>

Absorption/regeneration
non-conventional system for water extraction from atmospheric
air  
 Ahmed
Sultan, et al.

Abstract
-- The present work suggests a non-conventional method
of water production from atmospheric air, on a 24-h basis using
a compact system. The operation of the system is described and
its efficiency is defined. The system performs under forced
convection absorption and regeneration through a packed tower.
The packed tower consists of two identical columns, each of them
is packed with an identical bed. Each bed consists of vertical
multi-layers of cloth material impregnated with calcium chloride
solution of different concentrations. A numerical model, based
on the experimental results, has been developed to predict the
performance of the system under various operating conditions.
The system efficiency is found to have peak values at certain
cycle times, desiccant final concentration, regeneration
temperature and absorption air stream velocity. It is also found
that the maximum efficiency increases with initial concentration
and decreases with the increase of the regeneration air stream
velocity and absorption temperature.

[**https://www.sciencedirect.com/science/article/abs/pii/S096014810300020X**](https://www.sciencedirect.com/science/article/abs/pii/S096014810300020X)**Absorption/regeneration non-conventional system for
water extraction from atmospheric air****Ahmed Sultan****Abstract --** The present work suggests a
non-conventional method of water production from atmospheric
air, on a 24-h basis using a compact system. The operation
of the system is described and its efficiency is defined.
The system performs under forced convection absorption and
regeneration through a packed tower. The packed tower
consists of two identical columns, each of them is packed
with an identical bed. Each bed consists of vertical
multi-layers of cloth material impregnated with calcium
chloride solution of different concentrations. A numerical
model, based on the experimental results, has been developed
to predict the performance of the system under various
operating conditions. The system efficiency is found to have
peak values at certain cycle times, desiccant final
concentration, regeneration temperature and absorption air
stream velocity. It is also found that the maximum
efficiency increases with initial concentration and
decreases with the increase of the regeneration air stream
velocity and absorption temperature.  
  
**Introduction**  
Extraction of water from atmospheric air is considered one
of the important methods of fresh water supply, because air,
as a source of water, is renewable, clean and exists
anywhere. Several investigators have studied this problem.
These investigations can be classified into two main groups.
The first group deals with the cooling of air, while the
second group studies the absorptionaregeneration of the
moisture directly from the air.  
  
The extraction of water from atmospheric air can be done by
cooling air to a temperature below its dew point, where
moisture is condensed. Many investigations [1], [2], [3],
[4], [5] have studied this method. Wind energy was used [6],
[7] to circulate atmospheric air through the system
condenser in order to separate moisture from it. Another
approach for water extraction from atmospheric air is by
absorption of water from atmospheric air into solid or
liquid desiccant with subsequent separation of water from
the desiccant by heating and condensation of vapor [8], [9].  
  
Regeneration of an absorbent using solar energy was
investigated [10], [11]. A comparative study for economical
evaluation of the two methods mentioned above shows that the
second system is more economic [2]. This comparison was
carried out assuming the use of solar energy as the power
supply of the two systems, with the use of Li Br absorption
cycle for cooling system and applying Ca Cl2 as the working
desiccant for the absorptionaregeneration system.  
  
An integral desiccant/collector system for production of
fresh water from atmospheric air was studied [12]. The
system involved absorption of water vapor from ambient air
during the night and simultaneous desiccant regeneration and
vapor condensation during the day. Description and analysis
of the theoretical cycle for absorption of water from air
with subsequent regeneration, by heating, was presented in
[13]. Theoretical analysis showed that, strong and weak
solution concentration limits play a decisive role in the
value of cycle efficiency.  
  
The present study was conducted as a part of a full scale
project for water extraction from atmospheric air, whose
purpose has been to design, build and test a complete system
using cloth material impregnated with liquid desiccant. In
this work, a non-conventional system applicable for
periodically absorption and regeneration processes to
extract water from atmospheric air is proposed. A definition
of system efficiency based on the heat and mass balance
calculations is presented. This work also studies the
influence of air initial temperature, initial desiccant
concentration and time period on the system efficiency. A
suggested lay out of the water extraction plant is discussed
and experimental data are used to show the effect of
different parameters on the cycle efficiency.  
  
**Results and discussion**  
The system suggested in this work consists of periodically
absorbing regenerating columns. Each column consists of an
identical bed made of vertical multi-layers of cloth
material impregnated with calcium chloride solution of
different initial concentrations. The main aim of this work
is to study the effect of the air inlet temperature and air
mean velocity through both absorption and regeneration
columns, on system efficiency. Also the effect of initial
and final concentrations and cycle time  
  
**Conclusions**  
Analysis of the operation of the absorption/regeneration
system for water extraction from atmospheric air, in the
forced convection mode, has been developed. The system
efficiency is defined in terms of the system design
parameters. Also the effects of air temperature, air stream
velocity and initial and final concentrations through the
absorption and regeneration columns on the system efficiency
have been well defined...  
  


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**<https://www.sciencedirect.com/science/article/abs/pii/S0960148106000462>****Water production from air using multi-shelves
solar glass pyramid system** **A.E. Kabeel** **Abstract --** The capability of the glass pyramid
shape with a multi-shelf solar system to extract water from
humid air is explored. Two pyramids were used with different
types of beds on the shelves. The beds are saturated with
30% concentrated Calcium Chloride solution. The pyramid
sides were opened at night to allow the bed saturated with
moist air and closed during the day to extract the moisture
from the bed by solar radiation. The bed in the first
pyramid was made of saw wood while it is made of only cloth
in the second pyramid with the same dimensions. The system
was experimentally investigated at different climatic
conditions to study the effect of pyramid shape on the
absorption and regeneration processes. Preliminary results
have shown that the cloths bed absorbs more solution (9 kg)
as compared to the saw wood bed (8 kg). Adopting this
approach produces 2.5 L/day m2. The use of the pyramid shape
with four glass surfaces and multi-shelves enhances the
produced water by 90a95% compared with solar
desiccant/collector system with horizontal and corrugated
beds. Results also show that the clothes bed has higher
productivity than that of saw wood bed by about 5%. This is
due mainly to the greater carrying solution at the onset of
the experimental work. The obtained results may help in
designing more efficient system.,,  
  
**Conclusions**  
An integrated desiccant solar pyramid collector system for
producing water from ambient air has been designed,
constructed and experimentally tested. Calcium chloride is
applied as the working desiccant in this investigation. The
system operation involves night absorption of water from
ambient air by opening the four sides of the pyramid. During
the daytime, the four sides are closed and then the
desiccant regeneration as well as water vapor condensation
occurs...  
  


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**<https://www.sciencedirect.com/science/article/abs/pii/S1359431114008199>****Applied Thermal Engineering, Volume 75, 22
January 2015, Pages 513-531** **A review on the use of calcium chloride in applied
thermal engineering** **Kokouvi Edem, et al.** **Abstract --** The combination of its hygroscopy,
heat of hydration, the low to medium melting points of its
hydrates and its low material costs makes calcium chloride
and the respective hydrates an attractive substance for
various thermal processes. For refrigeration applications,
the ammonia sorption is of high significance. The use of
calcium chloride in pure or modified form is reviewed from
the application point of view. A short analysis of the
general physical and chemical properties highlights the
advantageous properties. An overview is given about its use
in the following applications: phase change material,
desiccant, heat pumps and refrigeration and thermal energy
storage. The advantages and challenges are discussed as well
as approaches for technical improvement.  
  
This paper reviews the use of calcium chloride in different
forms, pure or in a composite material, in thermal
applications. An emphasis is put on practical and
experimental applications in order to point out interesting
aspects of the material processing, properties, proven uses
and challenges that remain. The interest for calcium
chloride lies in the following non-exhaustive features and
advantages, depending on the application:  
  
Easy availability [13] because large quantities are produced
as by-product of industrial processes [14], [15].  
Subsequently, calcium chloride is one of the cheapest [13],
[16], [9] (0.3a0.4 USD kga1 [16], [17], [18], [19], [20], 2
USD kga1 [15]), even the cheapest commercially available
salt hydrate, depending on the application. This aspect
makes it very attractive for many applications in particular
those which need large quantities such as thermal storage
applications.  
A highly hygroscopic desiccating and sorption capacity [21],
[22], in solid or liquid state. This property is widely used
in industry, laboratories, commercial and domestic
buildings: it has been shown that anhydrous CaCl2 could
adsorb up to 90% of its own weight in moisture (water
vapour) at ambient temperature and pressure [23]. The
adsorption quantity is even higher than 100 wt% (weight
percent) with ammonia [24] because 1 mol of calcium chloride
can adsorb 8 mol of ammonia [25].  
 A relatively higher thermal conductivity, whether in
solid or liquid state, compared to other materials of the
same kind [26], [27].  
A better thermal [1], [16] and chemical stability [15] than
other salt hydrates  
A less corrosiveness than other salt hydrates [16], [28]  
A high latent heat of fusion (hexahydrate) [15]  
A small volume change during phase transition [15]  
Non-toxicity [29]  
In sorption processes, it can be paired with different
refrigerants (water, ammonia, methylamine, methanol,
ethanol: see Fig. 1) [30], allowing various applications at
various operation conditions  
Low or moderate temperature operating range [31]  
However, this material exhibits some undesirable behaviour:  
Possible liquefaction of the material after absorbing a
certain amount of water [24]  
Excessive swelling/expansion (2:1 [24]) and agglomeration in
particular when used in absorption cycle with ammonia [32],
[22], [24]: this degrades heat and mass transfer and results
in the decrease of reaction rate after several cycles [33]  
Depending on the use,
disintegration/decomposition/deterioration after several
operating cycles [25], [32], [34] when no special measure is
taken [13]  
Corrosive to certain metals in the presence of excess oxygen
because of chloride-induced corrosion [35]. However, this
corrosion problem is practically no real threat any more
when the process is run under near vacuum conditions
(limited air or oxygen in an adsorber [35]), which is
usually the case.  
Because of its multiple uses, the properties of calcium
chloride have been extensively studied; they are provided in
Table 1 for the calcium chloride hydrates. As for the
aqueous solution of calcium chloride and other working pairs
involving calcium chloride, Table 2 and Table 3 summarise
some references that give their properties. Solubility data
in water, methanol and ethanol [36] are given in Fig. 2.  
Various tetrahydrates are reported, among which the I+/- and I2
tetrahydrates are deemed to be stable [37], [38], [39].  
The pH of melted CaCl2A*6H2O has been reported to be 6 [28].
Corrosion data of the calcium chloride aqueous solution for
some materials can be found in Table 4. Corrosion is
increased with the mass fraction and the temperature. For
example, the stainless steel 304 is resistant to calcium
chloride aqueous solution when the mass fraction is at about
10 wt% and when the mass fraction is about 28 wt%, the
corrosion is about 0.003 mm yeara1 at 79 A degC [40]. Further
corrosion data on CaCl2A*6H2O have been reported by Cabeza et
al. [28]. The study indicates that CaCl2A*6H2O can be used in
a metal container of brass and copper for long term service.
Steel and aluminium are less resistant to CaCl2A*6H2O and are
recommended only for short term applications, but with
caution. As for stainless steel, no corrosion was observed
by the authors but they suspected that pitting could appear.  
  


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**<https://www.sciencedirect.com/science/article/abs/pii/S0735193322000094>****Water production enhancement from the air
moisture using nanofluids-experimental investigation and
exergo-enviroeconomic analysis** **Masoud Kave,et al.** *A device consisting of refrigeration and moisture
distillation cycles has been designed. Pure water from the
air moisture has been provided.* *The system performance has been enhanced using
nanofluids. An exergo-enviroeconomic analysis has been
performed.*   
**Abstract --** Nowadays, the expansion of communities
and population growth has further highlighted the need for
clean water. To solve this problem, various methods have
been proposed. Water extraction from the air moisture is of
these methods which involve cooling the air to its dew point
in which the moisture transforms from the gas to the liquid
phase. In the present study, a device consisting of a
refrigeration cycle and a moisture distillation cycle was
designed to provide pure water from the air moisture.
Additionally, it was tried to enhance the system performance
by dispersing nanoparticles such as Cu and Al2O3 into the
working fluid of the heat exchanger. In this study, the
influence of various parameters (including inlet air
velocity and ambient humidity) on the performance of the
system was investigated. Finally, an exergo-enviroeconomic
analysis was performed in terms of water production and
cost. Based on the results, with increasing the air humidity
from 40% to 60%, the amount of water production of the
system raised from 0.5 to 1.8 cc/min. It was also observed
that dispersion of Cu and Al2O3 nanoparticles enhanced the
water production by around 43% and 29%, respectively.
Moreover, an increment in inlet air velocity reduced the
water production; while increasing the air humidity had a
constructive effect on the system performance. The economic
analysis indicated that the water production during a year
increased by about 42% upon using Cu nanofluid as the
working fluid of the distillation cycle which declined the
water production cost by 32%.  
  
**Conclusion**  
The performance of a coupled system consisting of a
refrigerant cycle and a water distillation cycle was
comprehensively investigated. In the present research,
various parameters including mass flow rate of the produced
freshwater, COP, and total efficiency of the system were
studied under various working conditions. To study the
effect of ambient humidity, the system was examined at
ambient humidity of 40% and 60%. Moreover, the effect of
inlet air velocity on the copper spiral pipe was  
  


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**<https://www.sciencedirect.com/science/article/abs/pii/S0960148100001129>****Application of a solar desiccant/collector
system for water recovery from atmospheric air** **H.E Gad, A.M Hamed, I.I El-Sharkawy**  
**Abstract --** An integrated desiccant/solar collector
system for production of fresh water from atmospheric air is
described. The solar driven system provided about 1.5 l of
fresh water per square meter per day. The system involves
the absorption of water vapor from ambient air during the
night and simultaneous desiccant regeneration and water
vapor condensation during the day. To enhance the mass
transfer surface, a thick corrugated layer of cloth was used
as a bed to carry the liquid absorbent. In the nocturnal
phase of operation, air is allowed to penetrate the
desiccant bed. The airflow is driven by fans supported on
one side of the desiccant/solar collector unit. In this
study, the effects of different parameters on the absorption
and regeneration processes are discussed, and operational
conditions for the proposed equipment evaluated. Radiation
intensity, ambient temperature, bed temperature and
temperature of the glass surface were recorded. Also, the
productivity of the system during the day and under the
given operation conditions was plotted. A mathematical model
was prepared and its output compared with the analyzed
experimental data...  
  
**Conclusions**  
The performance of a desiccant/collector system with a thick
corrugated layer of blackened cloth to absorb water vapor at
night from atmospheric air with subsequent regeneration
during the day, using solar energy, was assessed. Actual
recorded results show that the solar operated system can
provide about 1.5 l of fresh water per square meter per day.
System operation and associated problems were discussed.
System efficiency was defined and values of more than 17%
were recorded...  
  


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**<https://www.sciencedirect.com/science/article/abs/pii/S1359431120311807>****Solar powered atmospheric water harvesting with
enhanced LiCl /MgSO4/ACF composite** **M. Ejeian, A. Entezari, R.Z. Wang** *Chemical adsorbents such as salt composites are still the
first option in Adsorptive Atmospheric Water
Harvesting.* *LiCl/MgSO4/ACF composite is a
suitable choice in AAWH, especially in areas with moderate
relative humidity.* *In an AAWH system, the
desorption rate is limited to the heat transfer rate of
the condenser.* *The higher the relative humidity,
the lower the energy intensity of the atmospheric water
harvesting.* *Our prototype produced 0.92 g/g water
in an arid climate powered by solar energy.*  
  
**Abstract --** Air humidity, as a source of water, is
more or less available everywhere. The sorption capacity of
water is a significant factor for the efficiency of
atmospheric water harvesting (AWH) systems, which are based
on the adsorption phenomenon. Lithium chloride has a high
water-uptake rate, but has a very low delinquency relative
humidity (DRH). Therefore, a host is required to make a
stable composite. Composite of activated carbon fiber (ACF)
and lithium chloride can keep the adsorbent immobile even
after the occurrence of deliquescence, which also causes the
three-phase sorption. However, the amount of salt inside the
composite is limited by the prevention of leakage. In this
paper, a binary salt composite is produced by a new method
in order to enhance the water sorption capacity in terms of
volume, and mass and the prevention the leakage. The effect
of adding MgSO4 to the composite has been experimentally
investigated for at different levels of relative humidity.
The results showed that sorption capacity per unit volume
and mass can be improved by the two-stage addition of MgSO4
without leaking in the adsorbent, reaching 0.78 g water/cm3
and 2.29 gwater/gadsorbent. The prototype made by the
selected composite showed that AWH energy intensity was
lower at higher relative humidity. The device was tested
successfully in an arid climate and produced 0.92
gwater/gadsorbent when maximum RH reached 35% during the
adsorption process.  
  
**Conclusions**  
In this study, LiCl/MgSO4/ACF composites were constructed by
using two different methods and compared with the LiCl/ACF
composite. The results showed that the two-step method had a
positive effect on net uptake water and sorption density,
because it creates a separate network structure for each
salt. The presence of MgSO4 in the composite, on the one
hand, leads to the expansion of the three-phase sorption
region, which improves the mass transfer in the system. On
the other hand, it increases...  
  


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**<https://www.sciencedirect.com/science/article/abs/pii/S0011916415002544>****Experimental investigation of solar powered
water production from atmospheric air by using composite
desiccant material aCaCl2/saw wooda** **Manoj Kumar, Avadhesh Yadav**  
*SGDBS (solar glass desiccant box type system) has been
used as an experimental setup.* *Six samples of
composite desiccant material CaCl2/saw wood have been
prepared.* *180 ml/kg/day of water can be produced
by using the composite desiccant material.* *For 500
ml/m2/day, 2.8 kg of the composite desiccant material are
required*  
**Abstract -**- New composite material for storage and
production of water from atmospheric air has been
investigated experimentally. Experiments have been performed
in the Indian climatic condition at NIT Kurukshetra, India
[29A deg 58a2 (latitude) North and 76A deg 53a2 (longitude) East] in
the month of October. Three numbers of newly designed solar
glass desiccant box type system (SGDBS) having a capture
area 0.36 m2 each, have been used. The design parameters for
the water production are height of glass from desiccant bed
at 0.22 m, inclination in angle at 30A deg, effective thickness
of glass at 3 mm and number of glazing as single. It is
found that water production rate depends upon the
concentration of CaCl2 in the saw wood. Maximum quantity of
water production by the composite material having 60%
concentration is 180 ml/kg/day.  
  


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**<https://www.researchgate.net/publication/245189660_Absorptionregeneration_non-conventional_system_for_water_extraction_from_atmospheric>** **July 2004Renewable Energy 29(9):1515-1535** **Absorption/regeneration non-conventional system for
water extraction from atmospheric** **Ahmed Abdel Rrazik Sultan**  
  
**Abstract --** The present work suggests a
non-conventional method of water production from atmospheric
air, on a 24-h basis using a compact system. The operation
of the system is described and its efficiency is defined.
The system performs under forced convection absorption and
regeneration through a packed tower. The packed tower
consists of two identical columns, each of them is packed
with an identical bed. Each bed consists of vertical
multi-layers of cloth material impregnated with calcium
chloride solution of different concentrations. A numerical
model, based on the experimental results, has been developed
to predict the performance of the system under various
operating conditions. The system efficiency is found to have
peak values at certain cycle times, desiccant final
concentration, regeneration temperature and absorption air
stream velocity. It is also found that the maximum
efficiency increases with initial concentration and
decreases with the increase of the regeneration air stream
velocity and absorption temperature.  
  


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[**https://www.sciencedirect.com/science/article/abs/pii/S0038092X18303451**](https://www.sciencedirect.com/science/article/abs/pii/S0038092X18303451)  
**Water generation from atmospheric air by using composite
desiccant material through fixed focus concentrating solar
thermal power** **Shobhit Srivastava, Avadhesh Yadav** *Scheffler reflector is used for fast water production.* *Composite
desiccant material LiCl/sand, CaCl2/sand & LiBr/sand
have been used.* *Absorption rate and regeneration
rate are carried out for water production.* *115a-ml/day
of water can be produced from CaCl2/sand.*  
**Abstract** -- In this manuscript, experimental
investigations have been performed in order to generate
water from atmospheric air by using different composite
materials under atmospheric condition of NIT, Kurukshetra,
Haryana, India [29A deg58a2 (latitude) North and 76A deg53a2
(longitude) East]. In this analysis, three composite
materials named LiCl/sand(CM-1), CaCl2/sand(CM-2) and
LiBr/sand (CM-3) have been used as salt with 37%
concentration and sand as a host material. The absorption
and regeneration processes have been performed to generate
water from atmospheric air. The absorption process has been
carried out at night in the open atmosphere whereas
regeneration process took place during the day time by using
newly designed 1.54a-m2 Scheffler reflector. The maximum
amount of water generated from CM-1, CM-2 and CM-3 are
90a-ml/day, 115a-ml/day and 73a-ml/day in 330a-min, 270a-min and
270a-min respectively and the annual cost of water generation
are $0.71, $0.53 and $0.86 respectively.  
  
**[US6490874](1Patents/US6490874B2.pdf)--** **Recuperative Environmental Conditioning Unit**

  
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**US8752330** **--
Plant Aid, Water Collection Sheet and Method**   
  


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**Marit
JAGTOYEN** **Auto Exhaust Water Recovery System**

[**http://lexcarb.com**](http://lexcarb.com)

**Development of
On-Board Water Recovery Unit for the Future Combat System
(FCS), HMMWV and the Tactical Quiet Generator**  

**Executive
Summary**  
The primary goal is to develop a fully integrated and
automated prototype system for the collection, purification
and storage of potable water from the exhaust gases of
military land vehicles. A heat exchanger & refrigeration
system is used to recover water generated during the
combustion process. The system is designed to operate under
desert conditions. A mesoscale heat exchanger is under
development at MesoSystems, Inc. This unit would be smaller
than conventional heat exchangers and could eventually fit
in the wheel arch of the HMMWV. The water cleanup is
performed using a purification train under development
consisting of an ultra-high efficiency glass fiber filter,
activated carbon and carbon fiber, zeolites and ion exchange
resins. The water purification canister design is
challenging since the water contains a mixture of organic
and inorganic acidic compounds. Currently, the water meets
drinking water standards with a TOC of < 2 ppm and in
most cases is less than 0.5 ppm, and a metal's content below
EPA regulated limits. Identification and removal of
remaining TOC is the focus of current research. For
comparison most municipal water supplies have a TOC of 2-3
ppm.

The successful
development of a system that produces potable water from
vehicle exhaust and is small enough to be of military
utility will augment a unit's water supply and reduce its
dependence on the supply infrastructure. This will lead to a
more mobile, deployable, and flexible force. The technology
will also provide water to small units in water scarce
environments. The system will provide safe, lifesaving,
drinking water in disaster relief and emergency
applications. It could also provide recreational vehicles in
water scarce environments with a critical survival tool...

 

But don't ask
Jagtoyen, who can often be seen driving a red Hum-Vee around
town, to chug a bottle of her diesel water just yet. There
are still traces of two unidentified compounds in the
otherwise pure water. They're probably harmless, she said,
but so far she's only sipping.

**US6581375** 
**--
Apparatus and Method for the Recovery and Purification of
Water from the Exhaust Gases of Internal Combustion Engines****[ PDF** **]**
 
  



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****[KOHAVI: Air Well](file:///RexResearch/kohavi/kohavi.htm)**** 


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Marc Parent : Air Well

<http://www.reuters.com/news/video?videoId=113820&videoChannel=6>  
Inventor Makes Water out of Air  
Oct 28 - A
French inventor has come up with a windmill that turns thin
air into water and says his creation could offer hope to
millions of people around the world who do not have enough
water.  
    
FR2833044 -- Machine for Producing Water
from Wind Energy  
[ PDF ]



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****[QINETIQ: Dew Collector](file:///C:/Users/Owner/Downloads/AirWellsLibrary/Kit/RexResearch/qinetiq/qinetiq.htm)**** 


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****[RETEZAR: Fontus Air Well](file:///C:/Users/Owner/Documents/CivKit/RexResearch/retezar/fontus.html)****


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****[RICHARDS: AquaMagic Water Generator](file:///C:/Users/Owner/Downloads/AirWellsLibrary/s/CivKit/RexResearch/aquamagic/aquamagic.html)****


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****[SHER: Air Well](file:///C:/Users/Owner/Documents/CivKit/RexResearch/sherairwell/sher.html)****


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****[THEILOW: Air Well](file:///C:/Users/Owner/Documents/CivKit/RexResearch/theilow/theilow.htm)**** 


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****[VITTORI: WarkaWater Airwell](file:///C:/Users/Owner/Documents/CivKit/RexResearch/vittori/Vittori.htm)**** 


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****[WHISSON: Air Well](file:///C:/Users/Owner/Documents/CivKit/RexResearch/whisson/whisson.htm)**** 


---

****[YAGHI: MOF Airwell](file:///C:/Users/Owner/Documents/CivKit/RexResearch/yaghiairwell/yaghi.html)****


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**[Fog Collectors](file:///C:/Users/Owner/Downloads/AirWellsLibrary/RexResearch/fog/fog.htm)**   


---

  
 **[HENG / LUO: Fog Collector](file:///C:/Users/Owner/Documents/CivKit/RexResearch/hengluo/hengluo.htm)**   


---

  
 **[McKINLEY: Fog Fence](file:///C:/Users/Owner/Documents/CivKit/RexResearch/fogfence/mckinley.html)**   


---

  
 ****[OLMO / GIL: Fog Collector](file:///C:/Users/Owner/Downloads/AirWellsLibrary/arch/olmofog/omo-gil.html)****   


---



---

******ARTICLES******

******Chem. Engg Transactions  
New Architectural Forms to Enhance Dew Collection  
Daniel Beysens, et al.  
[ [PDF](1Articles/BeysensArchFormsDew.pdf) ]****Abstract** -- Dew water is water vapour that
passively condenses from air. Once properly collected, it can
provide a useful supplementary water resource for plants and
humans. Its production can be significantly improved by using
specific materials and particular geometry. In this context,
new shapes for dew collectors are presented and their water
yields are compared with those of a 1 m 2 , 30A deg, inclined
planar condenser used as a standard. The experiments were
carried out in Pessac (SW France), situated about 45 km from
the Atlantic Ocean, during summer and fall 2009. In addition
to conical shapes, which have 30 % larger yields than the
planar reference condenser and whose functioning was simulated
numerically, two new families of forms are considered: egg-box
and origami types. The egg-box shape yields 9 % more water as
compared to the reference planar condenser, a result nearly
independent of the dew yield. In contrast, the origami shape
gives yields 150 % larger than the reference planar condenser
for events with high dew volumes and can show 400 % greater
yields for low dew volumes. These results are analysed and
discussed in terms of (i) radiative effects correlated with
the angular variation of sky emissivity, (ii) heat losses by
free and forced (wind) air convection and (iii) gravity water
flow. General rules to increase dew collection are introduced.  


---

 ******Production d'eau dans un ancien sarcophage A  Arles - sur
- Tech (France)  
D. Beysens, et al.******************[
[PDF](1Articles/BeysensArles.pdf) ]**********Abstact --** Depuis le 16A"me siA"cle, au moins,
un sarcophage scellA(c), situA(c) dans la cour de l'abbaye
d'Arles-sur-Tech (France), est rA(c)putA(c) produire des centaines
de litres d'eau par an. Beaucoup d'hypothA"ses ont A(c)tA(c) avancA(c)es
pour expliquer ce mystA"re. AprA"s avoir recueilli pendant
environ trois ans des donnA(c)es, nous concluons que cette
quantitA(c) d'environ 200 litres d'eau par an, est le bilan final
d'une entrA(c)e d'eau de pluie, de rosA(c)e condensA(c)e et
d'A(c)vaporation. Des dA(c)fauts dans la jonction du couvercle et du
corps du sarcophage permettent un A(c)change avec l'atmosphA"re...  


---

 ******FOG AND DEW COLLECTION PROJECTS IN CROATIA  
M. Mileta, et al.************[ [PDF](1Articles/MiletaFogCroatia.pdf) ]******  
**Abstract --** The present paper discusses the fog and dew
water collection in Croatia. ZaviA3/4an, the highest
meteorological station in Croatia( 1594m) is chosen for
collecting of fog water with a standard fog collector (SFC).
The highest daily collection rate was 27.8 L / mA2. The highest
daily collection rate in days without rain was 19.1 l/mA2. Dew
is also a noticeable source of water, especially during the
drier summer season. Dew condensers in Croatia have been
installed on the Adriatic coast (Zadar) and islands Vis and
BiA!evo. We report and discuss the data collected since 2003.
In the small BiA!evo island, a special roof has been designed
to improve the formation and collection of dew on a house.
Data from April 2005 will be presented.  
  



---

  
************<https://www.science.org/doi/10.1126/sciadv.aao5323>  
Electrostatically driven fog collection using
space charge injection  
A. Damak, et al.  
[ [PDF](1Articles/DamakESFogCollx.pdf) ]  
  
Abstract --************ Fog collection can be a
sustainable solution to water scarcity in many regions
around the world. Most proposed collectors are meshes that
rely on inertial collision for droplet capture and are
inherently limited by aerodynamics. We propose a new
approach in which we introduce electrical forces that can
overcome aerodynamic drag forces. Using an ion emitter, we
introduce a space charge into the fog to impart a net charge
to the incoming fog droplets and direct them toward a
collector using an imposed electric field. We experimentally
measure the collection efficiency on single wires, two-wire
systems, and meshes and propose a physical model to quantify
it. We identify the regimes of optimal collection and
provide insights into designing effective fog harvesting
systems.  


---

 ************<https://www.science.org/doi/epdf/10.1126/sciadv.aao5323>******Hydrol. Earth Syst. Sci., 19,
601a613, 2015  
Estimates of global dew collection potential on
artificial surfaces  
H. Vuollekoski, et al.******  
************[ [PDF](1Articles/VuollekoskiDew.pdf) ]**************Abstract** -- The global
potential for collecting usable water from dew on an
artificial collector sheet was investigated by utilizing 34
years of meteorological reanalysis data as input to a dew
formation model. Continental dew formation was found to be
frequent and common, but daily yields were mostly below 0.1
mm. Nevertheless, some water-stressed areas such as parts of
the coastal regions of northern Africa and the Arabian
Peninsula show potential for large-scale dew harvesting, as
the yearly yield may reach up to 100 L m^2 for a commonly
used polyethylene foil. Statistically significant trends
were found in the data, indicating overall changes in dew
yields of between A+/-10 % over the investigated time period.  


---

 ******Natural Resources, 2011, 2, 8-17  
Application of Solar Energy for Recovery of Water from
Atmospheric Air in Climatic Zones of Saudi Arabia  
Ahmed M. Hamed******   
************************[
[PDF](1Articles/HamedApplnSolEnergyNR2011.pdf) ]**************************Abstract** -- In the present work, an
investigation on the application of solar energy to heat
a sandy bed impregnated with calcium chloride for
recovery of water from atmospheric air is presented. The
study also aimed at evaluating the effects of different
parameters on the productivity of the system during
regeneration. These parameters include system design
characteristics and the climatic conditions. An
experimental unit has been designed and installed for
this purpose in climatic conditions of Taif area, Saudi
Arabia. The experimental unit which has a surface area
of 0.5 m 2, comprises a solar/desiccant collector unit
containing sandy bed impregnated with calcium chloride.
The sandy layer impregnated with desiccant is subjected
to ambient atmosphere to absorb water vapor in the
night. During the sunshine period, the layer is covered
with glass layer where desiccant is regenerated and
water vapor is condensed on the glass surface. Ambient
temperature, bed temperature and temperature of glass
surface are recorded. Also, the productivity of the
system has been evaluated. Desiccant concentration at
start of regeneration is selected on the basis of the
climatic data of Al-Hada region, which is located at
Taif area, Saudi Arabia. Experimental measurements show
that about 1.0 liter per m 2 of pure water can be
regenerated from the desiccant bed at the climatic
conditions of Taif. Liquid desiccant with initial
concentration of 30% can be regenerated to a final
concentration of about 44%. Desiccant concentration at
start of regeneration is selected on the basis of the
climatic data of Al-Hada region. The climate of Taif
city is dry compared with that for Al-Hada region. This
method for extracting water from atmospheric air is more
suitable for Al-Hada region especially in the fall and
winter.  


---

******Secheresse,
11 (4), Dec. 2000  
THE CASE FOR ALTERNATIVE FRESH WATER SOURCES  
D. Beysens, et al.******************************[
[PDF](1Articles/BeysenCaseAltWater.pdf) ]**************************Abstract** -- This paper describes
alternatives to the traditional methods of obtaining
fresh water. It covers the recovery of atmospheric
humidity, fog and water vapour, in addition to seawater
desalination, which is analysed briefly. It examines fog
recovery while focusing more closely on how the
condensation of atmospheric water vapour (dew) has been
realised in the past and why higher yields can now be
envisaged. Adsorption processes using regenerative
desiccants are also considered.  


---

******J.
Hydrology 405: 171-181 ( 2011 )  
A very large dew and rain ridge collector in the Kutch
area (Gujarat, India)  
G. Sharan, et al.******************************[
[PDF](1Articles/SharanVeyLargeDewColl.pdf) ]**************************Abstract** -- The worldas largest dew and
rain collecting system, comprised of ridge-and-trough
modules, was constructed in March 2006 at Panandhro in
the semi-arid area of Kutch (NW India). The main goals
were (i) to collect dew on a scale that could be
beneficial to the local population (ii) to determine the
efficiency of this new module shape, (iii) to determine
whether results obtained from small measurement
condensers can be projected to large condensers, (iv) to
apply a computational fluid dynamic simulation to
improve the condenser set-up. Preliminary studies
performed with four standard plane condensers of 1 m2
surface area, inclined 30A deg from horizontal, identified
Panandhro as a promising site. The cumulated dew water
during 192 days was 12.6 mm with a maximum of 0.556
mm/night. A large dew condenser (850 m 2 net total
surface) was designed with 10 ridge-and-trough modules.
The ridges are trapezoidal, 33 m long, 0.5 m wide at the
top, 2.2 m wide at the base and sloping 30A deg from
horizontal. The depth of the troughs between the ridges
is 0.5 m. A 2.5 cm thick polystyrene foam rests on the
surface as insulation with a radiative foil on top
(similar to that developed by OPUR, see www.opur.fr).
Numerical simulations using the computational fluid
dynamic software PHOENICS were performed. The most
profitable orientation was with the condenser oriented
back to the wind direction, a configuration that lowers
the wind velocity near the foil due to the combination
of free convection and wind  
recirculation flows. A comparison of water yields over
one year of measurements between four 1 m 2 plane
condensers and a 850 m 2 ridge condenser showed a 42%
lower yield on the large condenser. The difference is
attributed mainly to folds in the plastic foil allowing
water to fill the central ridge, thus decreasing
radiative cooling. The output for 2007 was 6545 L,
corresponding to 7.7 mm/day on average. The largest
event was 251.4 L/night (0.3 mm). Such a condenser can
also collect rain (and, to a lesser extent, fog).
Chemical and biological analyses showed that dew water,
once filtered and bottled, could be used for drinking
after a light treatment to increase the pH. The price of
this water could be lowered to reach 30% (dew only) or
even 3% (dew plus rain) of the market prize.  
  


---

 ************************CIBSE Technical Symposium,
DeMontfort University,
Leicestern UK a 6th and 7th
September 201******************EXPERIMENTAL
INVESTIGATIONS ON WATER RECOVERY FROM THE ATMOSPHERE IN
ARID HUMID REGIONS  
Esam Elsarrag, et al.******************************[
[PDF](1Articles/ElserragXptlInvstgnWatRecovAtm.pdf) ]************************ **Abstract** -- The Gulf region is one of the most arid
regions in the world. The lack of water is considered as the
most important problem. Annual rainfall is slight and erratic,
with an annual average of 81 millimetres in Doha. As a result,
renewable ground water resources are extremely limited and, in
addition, there are problems with groundwater salinity. The
atmosphere, endless source of water, contains a large quantity
of water in the form of vapour in varying amounts especially
in Gulf coastal region. In this paper two methods of
collecting water from the atmosphere are presented. First by
collecting condensate water, which is usually discarded, from
existing air conditioning systems. Experimental measurements
of water recovered from the atmosphere by existing air
conditioning systems have been carried out. The average rate
of condensed water collected during the experiments is found
to be about 7.2l/day per kW cooling. The experiments
demonstrate a cost efficient means of water recovery which can
be implemented in air conditioned buildings. The second method
is a novel tilted solar absorption/desorption system, modified
from conventional solar still, which used to collect water
from the atmosphere. Air is entered to the system at night
where water is absorbed by the desiccant. In the daytime the
desiccant is heated by solar energy to evaporate the absorbed
water. Calcium chloride is used as the desiccant and a
corrugated blackened surface is used to heat the desiccant in
daytime. It is found that the factors have the greatest effect
on the evaporation of water from the desiccant are the
temperature difference between the desiccant and the glass and
the desiccant flow rate. The higher evaporation rate from the
solar tilted unit is found to be about 0.18l/min per m2 of
solar collector area.  
  


---

 **European Journal of Science and Technology, Special Issue
32, pp. 991-999, December 2021  
A Literature Review on Extraction of Potable Water from
Atmospheric Air Using Solar Stills: Recent Developments  
Merdin DanA+/-Amaz, et al.  
[ [PDF](1Articles/LiteratureReviewExtractionPotable.pdf) ]  
  
Abstract --** Drinking water and utility water are
indispensable elements in meeting many vital needs, especially
drinking, cooking and cleaning. Unconscious agricultural
irrigation, pollution, and population growth cause water
scarcity that humanity must cope with. As a result of global
warming and climate change, especially the amount of potable
water is decreasing, making it difficult to access clean water
resources. The occupancy of drinking water sources decreases
in high temperature seasons and some of them even disappear.
This situation has made it necessary to search for alternative
methods to obtain drinking water. One of these methods is to
obtain potable water from atmospheric air containing high
amounts of water. With the widespread use of this method, the
scarcity of drinking water can be alleviated to a certain
extent. In this study, the processes of condensing the water
in the atmospheric air by using solar energy, which is a
renewable energy source, and thus obtaining potable water are
discussed. Efforts to increase the efficiency of obtaining
potable water by using various absorbents and by various
systemic solar still designs have yielded positive results. As
a result of this literature review, the limits of the studies
and their regional effectiveness were evaluated together. The
effect of temperature, velocity, humidity of the atmospheric
air and the amount of solar radiation on the process were
evaluated. It has been concluded that certain desiccant
materials with good water absorbers such as calcium chloride
and silica gel can be used effectively in the processes of
obtaining potable water from atmospheric air by developing
correct designs. It has been demonstrated that high
atmospheric air temperature, which is an important cause of
water scarcity, can be converted from disadvantage to
advantage by utilizing solar energy.


---

 **<https://www.academia.edu>**  
**WEENTECH
Proceedings in Energy, ICEEE 2016, 16th -18th August
2016  
Potential for Extracting Water from atmospherically
Jordanian Air  
Ahmad Al-Sarayrah**********************[
[PDF](1Articles/PotentialExtractingWaterfromatmosp.pdf) ]********************  
  
**Abstract --** This paper aims to provide solutions
for water supply in regions suffering from shortage of
fresh water, and contaminated water. It presents a
method to extract pure water from atmospheric air. It
depends on intensifying the water vapor from the air.
The plant was designed to perform the optimum levels to
produce high quality water with minimal electricity
consumption. The harvesting water was inspected and
analyzed based on ISO/IEC 17025 method to check the
purity water. This study also investigates the potential
of using a solar powered for atmospheric water
generation (AWG) as a new option for fresh water
production. A proposed solar AWG unit was assembled,
analyzed and modeled using HOM ER software. The results
demonstrated that the water produced by the water
extraction plant is pure, safe, economical, and
acceptable tasting. It can be used as drinking water
after treated by filter and disinfected by Ultra Violet
Light (UV) technique. The feasibility analysis showed
that there is a potential to adopt solar powered of AWG
as strategic and alternative option for a small area;
which is suffering from shortage of drinking water.  


---

**[https://www.mdpi.com/1996-1073/15/2/421](https://www.academia.edu)A Recent and Systematic Review on Water Extraction from
the Atmosphere for Arid Zones   
Suad H Danook**  
********************[ PDF ]**********************Abstract -**- Water is essential for food
security, industrial output, ecological sustainability,
and a countryas socioeconomic progress. Water scarcity
and environmental concerns have increased globally in
recent years as a result of the ever-increasing
population, rapid industrialization and urbanization,
and poor water resource management. Even though there
are sufficient water resources, their uneven circulation
leads to shortages and the requirement for portable
fresh water. More than two billion people live in
water-stressed areas. Hence, the present study covers
all of the research based on water extraction from
atmospheric air, including theoretical and practical
(different experimental methods) research. A comparison
between different results is made. The calculated
efficiency of the systems used to extract water from
atmospheric air by simulating the governing equations is
discussed. The effects of different limitations, which
affect and enhance the collectorsa efficiency, are
studied. This research article will be very useful to
society and will support further research on the
extraction of water in arid zones.  


---

**[https://www.researchgate.net/publication/285533435\_A\_technical\_review\_on\_the\_extraction\_of\_water\_from\_atmospheric\_air\_in\_arid\_zones](https://www.academia.edu)**  
********Journal of Heat and Mass
Transfer, Volume 4, Number 3, 2010, Pages 213-228.******
  
A Technical Review on the Extraction of Water from
Atmospheric Air in Arid Zones  
Prof Ayman A Aly**********************[
 [PDF](1Articles/ATECHNICALREVIEWONTHEEXTRACTIONOFWATER.pdf) ]**********************Abstract** -- Fresh water supply is one of
the most limiting conditions for the populations of arid
regions. The present paper covers the working principles
of systems and processes for extracting water from
atmospheric air. Moreover, a summary of the experimental
and analytical studies which investigate system
performance has been made. Some new designs that greatly
expand the solar desiccant technique for absorption with
subsequent regeneration are also introduced. The
research activities in this sector are still increasing
to solve the crucial points that make these systems not
yet ready to compete with other systems as water
distillation.  


---

**<https://www.academia.edu/89958072/Solar_Powered_Atmospheric_Water_Generation_and_Purification_System?email_work_card=title>****Development of Solar
Powered Atmospheric Water Generation and Purification
System   
Jromed Cheng**********************[
[PDF](1Articles/SolarPoweredAtmosphericWaterGenerati.pdf) ]********************...The
device mainly consists o\f condensing block for condensing the
moisture air and inlet fans for sucking air into system and
solar powered battery and external supply for to drive the
system. And last but not least the whole system is controlled
by the Arduino Un**o.**


---

 **<https://web.archive.org/web/20110614152852/http://www.iimahd.ernet.in/publications/data/2007-08-05Gsharan.pdf>Harvesting dew to supplement drinking water supply in
arid coastal villages of Gujarat  
Girja Sharan  
[ [PDF](1Articles/SharanHarvestDewGujarat.pdf) ]  
  
Abstract** -- Shortage of drinking water is chronic,
sever and widespread in Kutch - a hot and very arid region. It
is specially acute in coastal villages where surface sources
dry up rapidly and groundwater is not potable. Many of these
are listed as ano sourcea villages and are supplied water on
tanker-trucks daily from long distances. The conventional
efforts to conserve and augment water resources are all in
place. But one potential resource - dew - had remained
unnoticed. The possibility that it may also be a supplementary
resource was first noticed in the summer of 2001 when it was
observed that dew condensed frequently on a plastic- clad
greenhouse in Kothara, a village 15 km from the coast. That
led us first, to carry out systematic measurement, and then to
develop practical ways to harvest dew for human use  


---

 **Journal of Arid Environments  
Comment on aaThe moisture from the air as water resource in
arid region: Hopes, doubt and factsaa by Kogan and Trahtman  
D. Beysens, et al.  
[ [PDF](1Articles/BeysensJAE06.pdf)
]  
  
Abstract** -- Kogan and Trahtman [2003. The moisture from
the air as water resource in arid region: hopes, doubts and
facts. Journal of Arid Environments 53, 231a240] analysed the
functioning of a passive dew condenser built by F.I. Zibold in
1912 in Feodosia, and proposed a model to explain how
thousands of litres of condensed water might be generated per
day based on Ziboldas design. In a previous publication, some
of the present co-authors explained why it was not possible to
obtain high water yields with Zibold-style dew condensers and
that Zibold was apparently unaware that the stone heaps in
Feodosia were in fact ancient Scythian and Greek tombs. Kogan
and Trahtman [2003] take issue with our findings, thus the
reason for this comment.  


---

 **<https://www.mdpi.com/2673-7248/5/4/43>Textiles 2025, 5(4), 43  
Alternative and Sustainable Technologies for Freshwater
Generation: From Fog Harvesting to Novel Membrane-Based
Systems  
Musaddaq Azeem, et al.  
[ PDF ]  
  
Abstract** -- Water scarcity is an escalating global
challenge, driven by climate change and population growth.
With only 2.5% of Earthas freshwater readily accessible, there
is an urgent need to explore sustainable alternatives.
Textile-based fog collectors are advanced tools which have
shown great potential and have gained remarkable attention
across the world. This review critically evaluates emerging
technologies for freshwater generation, including desalination
(thermal and reverse osmosis (RO)), fog and dew harvesting,
atmospheric water extraction, greywater reuse, and solar
desalination systems, e.g., WaterSeer and Desolenator. Key
performance metrics, e.g., water yield, energy input, and
water collection efficiency, are summarized. For instance,
textile-based fog harvesting devices can yield up to 103
mL/min/m2, and modern desalination systems offer 40a60% water
recovery. This work provides a comparative framework to guide
future implementation of water-scarcity solutions,
particularly in arid and semi-arid regions**.**


---

 **<https://advanced.onlinelibrary.wiley.com/doi/full/10.1002/adfm.202306162>Bio-Inspired Fog Harvesting Meshes: A Review  
Brook S. Kennedy, Jonathan B. Boreyko  
  
Abstract --** Freshwater scarcity has become a critical
global challenge ainotecting some of  
the most vulnerable populations. In response, signiinotcant einotort
has focused on ways to increase access to this precious
resource. Within the context of geographical, cultural,
political, and technological factors governing freshwater
availability, atmospheric water harvesting (AWH) has
demonstrated tremendous promise to help address these
shortages.  
Speciinotcally, mesh-based fog harvesters have received
considerable attention for their passive qualities compared
with their energy-dependent technological siblings (sorbents,
condensation, etc.), yet their speciinotc water yield (SY) has
developed only modestly in recent decades. While the plant and
animal kingdom provide diverse examples of passive fog
collection, and science has developed a remarkable
understanding of these processes, much of this knowledge has
yet to be translated practically at scale. This is partially
due to challenges in mass-producing complex (often
micro-scale) structures observed in nature. Fortunately,
manufacturing technology is catching up with scientiinotc
understanding, especially at the scale of mesh design. To this
end, the review begins by surveying bioinspired research in
fog harvesting. Afterward, this study identiinotes milestones in
developing bioinspired fog harvesting meshes, concluding in a
discussion of future mesh research opportunities connecting
bioinspiration and emerging advanced manufacture...  
  


---

 **<https://www.sciencedirect.com/science/article/abs/pii/S0140196305001096?via%3Dihub>A comparative study of two large radiative dew water
condensers  
M. Muselli, D. Beysens, I. Milimouk  
  
Abstract --** In order to improve the yield of dew
condensation from atmospheric vapor, two large (30 m2 in area)
insulated plane radiative condensers, inclined at 30A deg, were
installed in Ajaccio (Corsica island, France; latitude
41A deg55a2N, longitude 8A deg48a2E). Prototype P1 was elevated such
that the underside was open and exposed. Prototype P2,
however, was enclosed on all sides and closer to the ground.
Both used a special radiative foil that enhances dew
formation. The period of observation for P1 was July 22,
2000aNovember 11, 2001, and for P2 was December 10,
2001aDecember 10, 2003. All data were compared with respect to
the same horizontal calibration plate of
polymethylmethacrylate (Plexiglas) placed at 1 m above the
ground on a sensitive recording balance. Water yield of both
prototypes were compared and correlated against meteorological
data (cloud cover, relative humidity, wind speed, condenser
temperature and air temperature). Both prototypes exhibit
improved performances when compared with the calibration
plate: more dew days (+16% and +15% for P1 and P2,
respectively); decrease of the humidity threshold (a3% and
a4.4% for P1 and P2); increase of dew yields for wind speeds
up to 3 m sa1. A model of the mass and thermal exchanges with
the ambient air was used. Two adjustable parameters (heat and
mass transfer coefficients) are used in the model. The values
of these parameters were found larger than the values obtained
in continental sites where dew forms with weak wind, thus
emphasizing the peculiarities of dew formation in windy
islands. When data are reduced with the calibration PMMA data,
prototype P1 provided average water yields slightly larger
than the enclosed prototype P2, a result that can be
attributed to the influence of surface thermal radiation.  


---

 **<https://link.springer.com/article/10.1007/s40899-015-0038-z>A review: dew water collection from radiative passive
collectors to recent developments of active collectors  
B. Khalil, et al.**


---

 **<https://www.researchgate.net/publication/277300109_Making_Cheap_Drinking_Water_from_Air>Making Cheap Drinking Water from Air  
Herman Vogel  
[ [PDF](1Articles/CheapDrinkingWaterfromAir.pdf) ]  
  
Abstract -**- How can we best apply basic technology to
assist the underprivileged and/or the recent disaster-hit
countries like Haiti? Daily hygiene and nourishment are among
the top needs for disaster ridden regions! Simply put, no
water means no hygiene and death. The Romans understood that
over two millennia ago a| and created their complexly beautiful
aqueduct networks for handling both fresh and wastewater!
Other ingenious water systems like aair wellsa have been found
in the city of Theodosia (cf: discovered in 1900 by Zibold,
see Ziboldas Collectors/Dehumidifiers) dating back to
Greco-Roman times during the Byzantine Empire. These were
strictly passive systems that naturally dehumidified air,
collecting its potable water in underground basins.


---

 **<https://www.nature.com/articles/2071173a0>Irrigation of Plants with Atmospheric Water within the
Desert  
I. GINDEL**


---

 **<https://www.youtube.com/watch?v=v7Fu0dp3iB8>Air Well Concept - On-Going Research  // Extreme
Budget**


---

 **<https://iwaponline.com/ws/article/24/11/3810/105774/Atmospheric-water-harvesting-as-a-sustainable-and>Atmospheric water harvesting as a sustainable and
resilient resource in arid climates: gaining insights from
ancient techniques  
Nathalie Verbrugghe, Ahmed Z. Khan  
  
Abstract --** Fog and dew, or atmospheric moisture, are
valuable complementary resources. Ancient civilisations
exploited these resources in harmony with the environment,
though information on their techniques is fragmented. This
review provides insights into the efficiency, evolution, and
relevance of ancient atmospheric water harvesting (AWH)
techniques from 5000 B.C. to the 1900s, alongside modern
techniques. An analytical framework and assessment are
presented to deduce their viability for replication, revival,
restoration, or redevelopment. Modern fog collectors yield an
average value of 3a10 L/m2/day and dew collectors 0.3a0.6
L/m2/day. Ancient fog collectors from Mexico and Chile
resembled modern collectors, while fog drip from trees offers
a natural alternative, collecting 10 L/m2/day. The stone drip
method shows potential in urban areas with extensive concrete
surfaces. Ancient dew collection techniques include
alchemists' dew collectors, lithic mulching for soil water
conservation, dew ponds for water retention, and stone-pile
condensers, which collected up to 360 L/day. Air wells,
however, were less effective. Ancient AWH techniques offer
valuable insights and can effectively supplement modern
collectors, enhancing resilience and water security,
especially in arid regions. Implementing AWH techniques
provides sustainable, decentralised, nature-based strategies
on a micro and macro scale for mitigating contemporary water
shortages amidst increasing climate challenges.


---

 **<https://doi.org/10.2166/aqua.2018.174>  
Journal of Water Supply: Research and Technology-Aqua (2018)
67 (4): 357a374.  
Roof-integrated dew water harvesting in CombarbalA!, Chile   
Danilo Carvajal; et al.  
  
Abstract -- D**ew harvesting can be a supplementary source
of freshwater in semiarid and arid areas. Several experiments
on small-scale dew condensers (usually of 1 m2) have been
carried out in many places in the world; however, few
experiments have been conducted on large-scale collectors
integrated into buildings. This work aims to assess one year
of dew water harvesting in CombarbalA! (Chile) using a painted
galvanised steel roof as collecting surface. The roof (36 m2)
was coated with a high-infrared-emissivity paint containing
aluminosilicate minerals (OPUR, France). Dew measurements were
conducted daily from September 2014 to August 2015. The dew
yield and its relationship with meteorological variables were
analysed. The results show that despite the low nocturnal
relative humidity throughout the year (average: 48%), dew
collection occurred on 56.1% of the recorded days. The daily
average collection rate was 1.9 L da1, with a maximum of 15 L
da1. The maximum daily dew yield is correlated strongly with
relative humidity and correlated weakly with air temperature
and wind speed. Considering the same rooftop can collect dew
and rain, it was estimated that over one year dew water could
contribute to roughly 8.2% of the total water collected,
considering both sources.


---

 **<https://doi.org/10.2166/aqua.2007.045>  
Journal of Water Supply: Research and Technology-Aqua (2007)
56 (4): 275a280.  
Feasibility of fog water collection: a case study from Oman  
Sabah A. Abdul-Wahab, et al.  
  
Abstract --** The aim of this study was to assess
different fog collectors in certain jabal (i.e. mountainous)
areas in the Dhofar Region of the Sultanate of Oman which
experience fog resulting from the Indian monsoons. A further
aim was to provide fog collectors in the close vicinity of
houses in the mountains to directly meet the needs of the
local residents. Experiments were conducted using three fog
collectors with different mesh materials namely; air
conditioner filter (AC; 6amaAa2.8am), green shade mesh
(12amaAa3am), and aluminum shade mesh (12amaAa3am). The
collectors were constructed close to the point of use. This
reduced the costs as the installation of pipelines would not
be needed to deliver the water. The results showed that all
fog collectors proved to be very effective in fog water
collection. Among all of them, the AC filter proved to be the
most effective. The total fog water collected during the
period of 77 days by AC filter, green shade mesh, and aluminum
shade mesh was 995, 880, and 753aL/m2, respectively. This
paper concludes with a set of recommendations for further in
depth assessment of the qualitative and quantitative aspects
of this water collection technology.


---

 **<https://iwaponline.com/ws/article/22/1/874/83172/Potential-of-harvesting-water-from-fog-and-dew>  
Potential of harvesting water from fog and dew water over
semi-arid and arid regions in Syria  
Majd M. Khalil, et al.  
  
Abstract --** Water is a significant primary resource on
the Earth's surface. Fresh water is essential for human beings
and for the stability and sustainable development of any
nation. Many regions in the interior of Syria have an
insufficient water balance. This has caused severe shortages
of freshwater as a result of climate change. Syria's main
source of fresh water, rivers and groundwater, suffers from
low levels due to the lack of rainfall amounts. The war in
Syria exacerbated water stress, in particular the effects of
the war on water sources such as the Euphrates River and the
aFeijaha source that feeds the capital Damascus. All of this
has prompted us to seek other non-traditional sources such as
atmospheric water, which is a renewable and relatively clean
source. This paper is considered to be the first of its kind
in Syria. Experimental results from semi-arid and arid regions
have shown good potential for harvesting dew and fog water as
a supplementary and complementary source to the existing
freshwater supply.


---

 **<https://iwaponline.com/ws/article/23/9/3675/97029/Fog-water-harvesting-potential-and-its-use-in>Water Supply (2023) 23 (9): 3675a3693.  
Fog water harvesting potential and its use in supplementary
irrigation of rainfed crops (winter wheat) in Abi-beyglu,
Ardabil (Iran)  
Amin Kanooni, Mohammad Reza Kohan  
  
Abstract -**- In arid and semi-arid areas where available
water resources are very limited, the application of
unconventional sources of water like the fog is of paramount
importance. In this paper, the feasibility of using a standard
fog collector (SFC) to collect fog water for complementary
irrigation of rainfed wheat in the Abi-beyglu area was
investigated. For this purpose, collected water volume was
measured on a daily basis during fog time in 2021. The water
demand of the winter wheat was estimated by the FAO
PenmanaMonteith equation under dry and normal conditions. Then
the contribution of the collected water to supply the water
demand of the wheat and the resultant increase in the yield
under two different scenarios, namely complementary irrigation
with 30 and 60 mm of collected water, was estimated using the
AquaCrop model. Results showed that it is feasible to obtain
an average water production of 3.6 L/m2/day over the studied
period. Upon irrigation with 30 and 60 mm of collected water
under dry and normal conditions, 26 and 34% of the water
deficiency for wheat farming was supplied, leading to
increased crop yields by 0.6 and 1.7 ton/ha, respectively.  


---

 **<https://iwaponline.com/ws/article/22/1/697/83295/Analysis-of-different-condensing-surfaces-for-dew><https://doi.org/10.2166/ws.2021.242>Water Supply (2022) 22 (1): 697a706.  
Analysis of different condensing surfaces for dew harvesting  
Larissa Corraide da Silva, et al.  
  
Abstract --** Due to water shortages in several places in
the world, alternative water sources such as atmospheric water
and greywater have been studied. Dew water harvesting by
passive radiative cooling is an unconventional water source
that is easy to use, install, and shows great potential in
several places in the world. This paper aims to experimentally
evaluate the dew yield through passive radiative cooling in
Vicosa city, Minas Gerais, Brazil by using standard white
plastic for dew harvesting, developed by the International
Organization for Dew Utilization (OPUR), polypropylene
plastic, black plastic, packaging tape, and anodized aluminum
as condensing surfaces during two different periods. The
polypropylene plastic and packing tape materials used in this
present research have not been researched before in the
literature. However, they have demonstrated potential for
harvesting dew. As a result, the average water collected was,
respectively, 0.151, 0.135, 0.140, 0.127, and 0.046 mm/night
using the OPUR standard plastic, polypropylene plastic, black
plastic, and packaging tape, and anodized aluminum as
condensing surfaces. Although relatively small water volumes
were harvested, this water should not be neglected since it
can supplement the water demand for irrigation, human and
animal consumption, among other uses in drought periods.


---

 **<https://interestingengineering.com/lists/everything-you-need-to-know-about-air-to-water-devices>  
Here Are the Most Advanced Methods to Extract Plentiful
Water From Thin Air  
*Turns out, the moisture farms in Star Wars might be
possible.*  
Christopher McFadden**


---

 **<https://www.darpa.mil/research/programs/atmospheric-water-extraction>  
AWE: Atmospheric Water Extraction  
  
Summary**Water transport is as mission-critical and as logistically
challenging as fuel transport for the U.S. military. Meeting
deployed military water needs requires equipment resources,
consumes fuel, and endangers personnel.   
  
The goal of DARPAas Atmospheric Water Extraction (AWE) program
is to provide potable freshwater for a range of military,
stabilization, and humanitarian needs through the development
of small, lightweight, low-powered, distributable systems that
extract potable water from the atmosphere to meet the drinking
needs of individuals and groups, even in extremely arid
climates.  
  
AWE seeks to develop next-generation, scalable sorbent
materials that can rapidly extract water from ambient air and
leverage advanced modeling, innovative engineering, and
additive manufacturing methods to achieve a substantial
reduction in the size, weight, and power (SWaP) requirements
compared to current atmospheric water generation technologies.  
  
AWE will address water needs in two tracks: expeditionary and
stabilization. The expeditionary unit will provide sufficient
drinking water for an individual warfighter, with SWaP
parameters restricted by the need for portability and
operation in austere environments.   
  
The stabilization device will provide the daily drinking needs
for up to ~150 people (i.e., a company or humanitarian
mission), with SWaP requirements tailored to resources
available to missions of that scale.  
  


---

 **<https://www.reuters.com/technology/spanish-engineers-extract-drinking-water-thin-air-2021-08-04/>Spanish engineers extract drinking water from thin air  
Mariano Valladolid, Jon Nazca**  
A Spanish company has devised a system to extract drinking
water from thin air to supply arid regions where people are in
desperate need.  
"The goal is to help people," said Enrique Veiga, the
82-year-old engineer who invented the machine during a harsh
drought in southern Spain in the 1990s. "The goal is to get to
places like refugee camps that don't have drinking water."  
The devices made by his company, Aquaer, are already
delivering clean, safe water to communities in Namibia and a
Lebanese refugee camp...  
While other water generators based on similar technology
require high ambient humidity and low temperatures to function
effectively, Veiga's machines work in temperatures of up to 40
Celsius (104F) and can handle humidity of between 10% and 15%.  
A small machine can produce 50-75 litres a day, and be easily
carried on a trolley, but bigger versions can produce up to
5,000 litres a day.  
  


---

  
**<https://www.oas.org/dsd/publications/unit/oea59e/ch12.htm>1.3 Fog harvesting**  
This innovative technology is based on the fact that water can
be collected from fogs under favorable climatic conditions.
Fogs are defined as a mass of water vapor condensed into small
water droplets at, or just above, the Earth's surface. The
small water droplets present in the fog precipitate when they
come in contact with objects. The frequent fogs that occur in
the arid coastal areas of Peru and Chile are traditionally
known as camanchacas. These fogs have the potential to provide
an alternative source of freshwater in this otherwise dry
region if harvested through the use of simple and low-cost
collection systems known as fog collectors. Present research
suggests that fog collectors work best in coastal areas where
the water can be harvested as the fog moves inland driven by
the wind. However, the technology could also potentially
supply water for multiple uses in mountainous areas should the
water present in stratocumulus clouds, at altitudes of
approximately 400 m to 1 200 m, be harvested. ...  
  


---

 **<https://www.sciencedirect.com/science/article/abs/pii/0169809589900367>Atmospheric Research. Volume 24, Issues 1a4, December
1989, Pages 53-69  
The collection efficiency of a massive fog collector  
Robert S. Schemenauer, Paul I. Joe  
  
Abstract --** Very large (48 m2) fog-water collectors are
being used on the coastal mountains in northern Chile to
generate water. The microphysical characteristics of the high
elevation fog (camanchaca) have been examined and the
collection efficiency of the collectors measured. The
camanchaca exhibits characteristics of clouds, reflecting its
source as a marine stratocumulus deck. Droplet mean volume
diameters (MVD) in ten cases ranged from 10.8 to 15.3 I1/4m.
Droplet concentrations were typically 400 cma3 with fog liquid
water contents ranging from 0.22 to 0.73 g ma3.  
  
The large fog-water collectors consist of a double layer of
mesh made from a 1-mm wide flat polypropylene ribbon. The
theoretical collection efficiencies of a 1-mm wide ribbon, for
droplets with the observed MVD, at wind speeds from 2 to 8 m
sa1, are 75 to 95%. The field measurements of the collection
efficiency of the mesh at the centerline of a large collector
gave values of a1/466% (3.5a6.5 m sa1; 11 I1/4m MVD). This is in
good agreement with the theoretical value for a single ribbon
once the areal coverage of the mesh is taken into account. At
lower windspeeds, the measured collection efficiencies dropped
to a1/426% (1.9 m sa1; 15 I1/4m MVD). A simple parameterization of
the mesh collection efficiency allowed some properties of
meshes to be examined, e.g. the mesh shows a marked decrease
in droplet collection as the ribbon width increased while
maintaining a constant percentage areal coverage.  
  
The measured water output from the large collector was 2.9
times lower than predicted using the measured amount of water
removed at the centerline and the wind speed 6m upstream. This
implies a large-collector efficiency of only a1/420%. This low
value may result from a lowering of wind speed as the fog
approaches the mesh, a reduced collection efficiency away from
the centerline, and water losses in the system.  


---

 **<https://www.sciencedirect.com/science/article/abs/pii/S0168192309001592>Agricultural and Forest Meteorology, Volume 149, Issue
11, 3 November 2009, Pages 1896-1906  
Prospective use of collected fog water in the restoration of
degraded burned areas under dry Mediterranean conditions  
MarA-a J. Estrela, et al.   
  
Abstract --** A mountainous plot located in the interior
of the Valencia region (east coast of the Iberian Peninsula)
was identified for reforestation using the fog-water
collection potential prevailing in the area. Fog data were
obtained by means of an instrument ensemble consisting of a
passive cylindrical fog-water collector, a rain gauge, a wind
direction and velocity sensor and a temperature and humidity
probe. Preliminary results gave rise to the additional
deployment of a low-cost 18-m2 flat-panel collector connected
to three 1000-l tanks for larger scale fog-water collection
and storage. The 2007 annual rate of fog water that could be
derived from the instrument ensemble amounted to 3.3 l/m2/day,
which turn out to fill up the storage tanks completely in only
5 months, even though the flat-panel collector could not be
operative 100% of the time. The study made use of the in situ
stored water and a micro-irrigation network to irrigate a plot
of reforestation seedlings through small water pulses
localized deep in the planting hole during the summer dry
period. Until the present, this forest location had always
shown a difficult self-recovery due to the high level of land
degradation resulting from recurrent forest fires in the past.
Results indicate that survival rates and seedling performance
of the two species planted, Pinus pinaster and Quercus ilex,
improved with the use of small timely waterings and additional
treatments with composted biosolid.


---

 **<https://www.sciencedirect.com/science/article/abs/pii/S0169809502000960>Atmospheric Research, Volume 64, Issues 1a4,
SeptemberaOctober 2002, Pages 251-259  
Exploring fog as a supplementary water source in Namibia  
E.S Shanyengana, et al.  
  
Abstract** -- Namibia is an arid country where many rural
and urban centres depend on ephemeral rivers for their water
supply. These water sources are, however, limited and display
seasonal salinisation. Fog occurs along the coast and extends
for some distance inland, and it could be used as a source of
drinking water. Data on groundwater salinisation and fog
deposition were collected at villages of the indigenous
communities and at the Gobabeb Training and Research Centre
(GTRC) in the Central Namib Desert. Fog collection experiments
were done with Standard Fog Collectors (SFCs) and 1-m2 fog
collectors made from the Raschel mesh that is used in SFCs
from 1996 onwards. The results indicate that fog occurs
throughout the year and that it has low major ion
concentrations (chemical composition). The period of high fog
deposition coincides with that of high groundwater salinity
and would suit mixing of the two waters to provide water of
good drinking quality to people in these areas. In conclusion,
fog is a viable source of water in the Namib and could
supplement traditional sources in rural settlements and
perhaps also in urban water supply schemes in this region as
in other parts of the world where it is used as a source of
drinking water.  
  


---

 **<https://www.sciencedirect.com/science/article/abs/pii/S0169809502000947>Atmospheric Research, Volume 64, Issues 1a4,
SeptemberaOctober 2002, Pages 227-238  
The implementation of fog water collection systems in South
Africa  
J Olivier, C.J de Rautenbach  
  
Abstract --** Two fog water collection systems (FWCS)
have been implemented in South Africa. Both are located in
areas where communities experience acute water shortages but
which are prone to frequent fog episodes. The first was
located at a high elevation site at the Tshanowa Junior
Primary (JP) School in the Soutpansberg located in the
Northern Province and the other near a small rural community
at Lepelfontein along the West Coast. The former represents a
mountainous site, while the latter is located on a low level
coastal plain. The principal aim of the projects was to
implement operational FWCSs to supply the communities with
water. During the period 1999 to 2001 the total recorded cloud
water yields at the Tshanowa JP School and Lepelfontein water
collection sites were in the region of 72 422 and 148 691 l,
respectively. This is equivalent to just over 2 l ma2 daya1 at
the Tshanowa JP School and 4.6 l ma2 daya1 at the Lepelfontein
site. Despite the relatively low average daily yields
recorded, the total water volume collected on a particular day
may be considerable. In fact, at both sites the maximum daily
yield exceeded 3800 l. Fog deposition accounted for around 25%
and 88% of the total water yield measured at the Tshanowa JP
School and Lepelfontein sites, respectively. Both experiments
indicated that fog water collection holds considerable
potential as an alternative water source in the mountainous
regions and along the West Coast of South Africa.


---

 **<https://www.sciencedirect.com/science/article/abs/pii/S0169809507002116>Atmospheric Research, Volume 87, Issues 3a4, March 2008,
Pages 324-337  
Fog collection in the western Mediterranean basin (Valencia
region, Spain)  
MarA-a J. Estrela, et al.  
  
Abstract --**Four different mountainous locations were
selected in the Valencia region, East coast of the Iberian
Peninsula, for fog water collection studies. Data for 2004
were obtained by means of an instrument ensemble consisting
essentially of a passive cylindrical fog water collector, a
raingauge, a wind direction and velocity sensor and a
temperature and humidity probe. An approximate data reduction
technique was also found for this specific ensemble to
eliminate the simultaneous rain water component from the fog
water measurements. Main results indicate that fog water
collection holds significant potential in this region, and
especially for southern locations. Annual rates of fog water
yield can be as high as 7.0 l/m2/day in the southern
locations, in contrast to 2.0 l/m2/day collected at one site
in a northern location. The highest summer fog water yield was
4.6 l/m2/day, a relatively large value. Except for the summer
period, fog episodes delivering sizeable water volumes are
inherently coupled to rainfall. Hourly frequencies of fog
collection were also examined to show a distinct daily cycle
in summer, denoting orographic fog formation during this
period. Lastly, winds were analysed to resolve the most
suitable directions for fog collector alignment.


---

 **<https://www.nature.com/articles/s41467-021-23174-0>Nature Communications volume 12, Article number: 2797
(2021)   
All-day fresh water harvesting by microstructured hydrogel
membranes  
Ye Shi, Ognjen Ilic, Harry A. Atwater & Julia R. Greer   
  
Abstract --** Solar steam water purification and fog
collection are two independent processes that could enable
abundant fresh water generation. We developed a hydrogel
membrane that contains hierarchical three-dimensional
microstructures with high surface area that combines both
functions and serves as an all-day fresh water harvester. At
night, the hydrogel membrane efficiently captures fog droplets
and directionally transports them to a storage vessel. During
the daytime, it acts as an interfacial solar steam generator
and achieves a high evaporation rate of 3.64akgama2 ha1 under
1 sun enabled by improved thermal/vapor flow management. With
a homemade rooftop water harvesting system, this hydrogel
membrane can produce fresh water with a daily yield of
~34aLama2 in an outdoor test, which demonstrates its potential
for global water scarcity relief.  


---

 **<https://pubs.acs.org/doi/10.1021/acsami.7b17488>Fog Harvesting with Harps  
Weiwei Shi, et al.  
  
Abstract --** Fog harvesting is a useful technique for
obtaining fresh water in arid climates. The wire meshes
currently utilized for fog harvesting suffer from dual
constraints: coarse meshes cannot efficiently capture
microscopic fog droplets, whereas fine meshes suffer from
clogging issues. Here, we design and fabricate fog harvesters
comprising an array of vertical wires, which we call afog
harpsa. Under controlled laboratory conditions, the
fog-harvesting rates for fog harps with three different wire
diameters were compared to conventional meshes of equivalent
dimensions. As expected for the mesh structures, the mid-sized
wires exhibited the largest fog collection rate, with a
drop-off in performance for the fine or coarse meshes. In
contrast, the fog-harvesting rate continually increased with
decreasing wire diameter for the fog harps due to efficient
droplet shedding that prevented clogging. This resulted in a
3-fold enhancement in the fog-harvesting rate for the harp
design compared to an equivalent mesh.  
  


---

 **<https://en.wikipedia.org/wiki/Air_well_(condenser)>AirWells**


---

 **<https://www.youtube.com/watch?v=vqKDNwGgN-w>How To Get Water From The Air Around You // TNT Omnibus**


---

 **<https://www.sciencedirect.com/science/article/abs/pii/0022169495029397?via%3Dihub>Water recovery from dew  
V.S. Nikolayev, D. Beysens, A. Gioda, I. Milimouka, E.
Katiushin, J.-P. Morel  
  
Abstract --** The recovery of clean water from dew has
remained a longstanding challenge in many places all around
the world. It is currently believed that the ancient Greeks
succeeded in recovering atmospheric water vapour on a scale
large enough to supply water to the city of Theodosia
(presently Feodosia, Crimea, Ukraine). Several attempts were
made in the early 20th century to build artificial
dew-catching constructions which were subsequently abandoned
because of their low yield. The idea of dew collection is
revised in the fight of recent investigations of the basic
physical phenomena involved in the formation of dew. A model
for calculating condensation rates on real dew condensers is
proposed. Some suggestions for the aideala condenser are
formulated.  


---

 **<https://www.amusingplanet.com/2016/08/achille-knapens-air-well.html>Achille Knapenas Air Well  
Kaushik Patowary**

**![](1knapen.gif)
![](achille-knapen-air-well-12.jpg) ![](achille-knapen-air-well-22.jpg) ![](achille-knapen-air-well-46.jpg) ![](achille-knapen-air-well-52.jpg) ![](achille-knapen-air-well-62.jpg)**



---

 **<https://www.researchgate.net/publication/341480904_Large_Scale_Dew_Collection_as_a_Source_of_Fresh_Water_Supply>Large Scale Dew Collection as a Source of Fresh Water
Supply  
Anil Rajvanshi  
  
Abatract --** A scheme for large scale dew collection as
a source of freshwater supply is outlined in the present
paper. The scheme envisages bringing cold seawater (5A degC) from
about 500 meters depth and about 5 km from the shore, in 4,
1.22 m diameter plastic pipes. It then passes through a heat
exchanger field with an area of 1.29 A 105 m2 (1.39 A 106 ft2)
where it condenses 643m3 of dew over the 24 hour period. The
pumping of seawater from the sea and through the field is
accomplished by three 200 kW wind machines. Technical and
economical feasibility of the scheme is analysed and the
possibility of marine culture as a source of food is explored.
The present scheme is economically not feasible as compared to
a reverse osmosis facility of equivalent capacity.


---

  
**<https://interestingengineering.com/lists/everything-you-need-to-know-about-air-to-water-devices>Here Are the Most Advanced Methods to Extract Plentiful
Water From Thin Air***Turns out, the moisture farms in Star Wars might be
possible.* **Christopher McFadden**


---

 **<https://www.tsunamiproducts.com/>Tsunami Products**At Tsunami Products, we design and build machines that
extract water from humidity in the air a efficiently and
economically.


---

 **<https://www.newscientist.com/article/2177538-nanofibre-net-draws-drinking-water-from-the-air-for-drought-hit-people/>Nanofibre net draws drinking water from the air for
drought-hit people  
Frank Swain**...Fog nets usually consist of a sheet of polythene mesh
strung between two poles. Passing water vapour condenses on
the small fibres and trickles down into collection bottles
below.  
  
However, the yield of these nets is often limited and the
water only flows on foggy days. The technology is also
restricted to mountainous regions where warm, wet air arriving
from the coast is forced up steep slopes, where it cools and
condenses as fog.  
  
Shing-Chung Josh Wong at the University of Akron in Ohio, US
and his team created a new material that they believe will be
a large improvement. They used electrospun polymers a a
technique which allowed them to create nanoscale fibres. These
are tangled around fragments of expanded graphite, like
spaghetti around meatballs. The fibres provide a large surface
area for droplets to condense onto, and the graphite
encourages the water to drip out of the material when it is
squeezed or heated.  
  
Wong says that harvesters made with these nanofibres could
yield up to 180 litres of water per square metre every day. In
comparison, a commercial system currently in use in Morocco
only produces around 30 litres per square metre per day.  
 **[US2023084610](1Patents/US2023084610A1.pdf)
--  FRESHWATER HARVESTING ASSEMBLY UTILIZING
WATER-SORPTION MATERIAL WITHIN HIERARCHICAL COMPONENT**


---

 **<https://www.darpa.mil/research/programs/atmospheric-water-extraction>AWE: Atmospheric Water Extraction  
  
Summary --** Water transport is as mission-critical and
as logistically challenging as fuel transport for the U.S.
military. Meeting deployed military water needs requires
equipment resources, consumes fuel, and endangers personnel.   
  
The goal of DARPAas Atmospheric Water Extraction (AWE) program
is to provide potable freshwater for a range of military,
stabilization, and humanitarian needs through the development
of small, lightweight, low-powered, distributable systems that
extract potable water from the atmosphere to meet the drinking
needs of individuals and groups, even in extremely arid
climates.  
  
AWE seeks to develop next-generation, scalable sorbent
materials that can rapidly extract water from ambient air and
leverage advanced modeling, innovative engineering, and
additive manufacturing methods to achieve a substantial
reduction in the size, weight, and power (SWaP) requirements
compared to current atmospheric water generation technologies.  
  
AWE will address water needs in two tracks: expeditionary and
stabilization. The expeditionary unit will provide sufficient
drinking water for an individual warfighter, with SWaP
parameters restricted by the need for portability and
operation in austere environments.   
  
The stabilization device will provide the daily drinking needs
for up to ~150 people (i.e., a company or humanitarian
mission), with SWaP requirements tailored to resources
available to missions of that scale.  


---

 **<https://www.sciencedirect.com/science/article/abs/pii/S0168192309001592>Agricultural and Forest Meteorology ,Volume 149, Issue
11, 3 November 2009, Pages 1896-1906  
Prospective use of collected fog water in the restoration of
degraded burned areas under dry Mediterranean conditions  
MarA-a J. Estrela, et al.   
  
Abstract --** A mountainous plot located in the interior
of the Valencia region (east coast of the Iberian Peninsula)
was identified for reforestation using the fog-water
collection potential prevailing in the area. Fog data were
obtained by means of an instrument ensemble consisting of a
passive cylindrical fog-water collector, a rain gauge, a wind
direction and velocity sensor and a temperature and humidity
probe. Preliminary results gave rise to the additional
deployment of a low-cost 18-m2 flat-panel collector connected
to three 1000-l tanks for larger scale fog-water collection
and storage. The 2007 annual rate of fog water that could be
derived from the instrument ensemble amounted to 3.3 l/m2/day,
which turn out to fill up the storage tanks completely in only
5 months, even though the flat-panel collector could not be
operative 100% of the time. The study made use of the in situ
stored water and a micro-irrigation network to irrigate a plot
of reforestation seedlings through small water pulses
localized deep in the planting hole during the summer dry
period. Until the present, this forest location had always
shown a difficult self-recovery due to the high level of land
degradation resulting from recurrent forest fires in the past.
Results indicate that survival rates and seedling performance
of the two species planted, Pinus pinaster and Quercus ilex,
improved with the use of small timely waterings and additional
treatments with composted biosolid.  


---

 **<https://www.sciencedirect.com/science/article/abs/pii/S0169809502000960>Atmospheric Research, Volume 64, Issues 1a4,
SeptemberaOctober 2002, Pages 251-259  
Exploring fog as a supplementary water source in Namibia  
E.S Shanyengana, et al.  
  
Abstract --** Namibia is an arid country where many rural
and urban centres depend on ephemeral rivers for their water
supply. These water sources are, however, limited and display
seasonal salinisation. Fog occurs along the coast and extends
for some distance inland, and it could be used as a source of
drinking water. Data on groundwater salinisation and fog
deposition were collected at villages of the indigenous
communities and at the Gobabeb Training and Research Centre
(GTRC) in the Central Namib Desert. Fog collection experiments
were done with Standard Fog Collectors (SFCs) and 1-m2 fog
collectors made from the Raschel mesh that is used in SFCs
from 1996 onwards. The results indicate that fog occurs
throughout the year and that it has low major ion
concentrations (chemical composition). The period of high fog
deposition coincides with that of high groundwater salinity
and would suit mixing of the two waters to provide water of
good drinking quality to people in these areas. In conclusion,
fog is a viable source of water in the Namib and could
supplement traditional sources in rural settlements and
perhaps also in urban water supply schemes in this region as
in other parts of the world where it is used as a source of
drinking water.


---

 **<https://www.sciencedirect.com/science/article/abs/pii/S0169809502000947>Atmospheric Research, Volume 64, Issues 1a4,
SeptemberaOctober 2002, Pages 227-238  
The implementation of fog water collection systems in South
Africa  
J Olivier, C.J de Rautenbach  
  
Abstract --** Two fog water collection systems (FWCS)
have been implemented in South Africa. Both are located in
areas where communities experience acute water shortages but
which are prone to frequent fog episodes. The first was
located at a high elevation site at the Tshanowa Junior
Primary (JP) School in the Soutpansberg located in the
Northern Province and the other near a small rural community
at Lepelfontein along the West Coast. The former represents a
mountainous site, while the latter is located on a low level
coastal plain. The principal aim of the projects was to
implement operational FWCSs to supply the communities with
water. During the period 1999 to 2001 the total recorded cloud
water yields at the Tshanowa JP School and Lepelfontein water
collection sites were in the region of 72 422 and 148 691 l,
respectively. This is equivalent to just over 2 l ma2 daya1 at
the Tshanowa JP School and 4.6 l ma2 daya1 at the Lepelfontein
site. Despite the relatively low average daily yields
recorded, the total water volume collected on a particular day
may be considerable. In fact, at both sites the maximum daily
yield exceeded 3800 l. Fog deposition accounted for around 25%
and 88% of the total water yield measured at the Tshanowa JP
School and Lepelfontein sites, respectively. Both experiments
indicated that fog water collection holds considerable
potential as an alternative water source in the mountainous
regions and along the West Coast of South Africa.  


---

 **<https://www.sciencedirect.com/science/article/abs/pii/S0169809507002116>Atmospheric Research, Volume 87, Issues 3a4, March 2008,
Pages 324-337  
Fog collection in the western Mediterranean basin (Valencia
region, Spain)  
MarA-a J. Estrela, et al.  
  
Abstract --** Four different mountainous locations were
selected in the Valencia region, East coast of the Iberian
Peninsula, for fog water collection studies. Data for 2004
were obtained by means of an instrument ensemble consisting
essentially of a passive cylindrical fog water collector, a
raingauge, a wind direction and velocity sensor and a
temperature and humidity probe. An approximate data reduction
technique was also found for this specific ensemble to
eliminate the simultaneous rain water component from the fog
water measurements. Main results indicate that fog water
collection holds significant potential in this region, and
especially for southern locations. Annual rates of fog water
yield can be as high as 7.0 l/m2/day in the southern
locations, in contrast to 2.0 l/m2/day collected at one site
in a northern location. The highest summer fog water yield was
4.6 l/m2/day, a relatively large value. Except for the summer
period, fog episodes delivering sizeable water volumes are
inherently coupled to rainfall. Hourly frequencies of fog
collection were also examined to show a distinct daily cycle
in summer, denoting orographic fog formation during this
period. Lastly, winds were analysed to resolve the most
suitable directions for fog collector alignment.  


---

 **<https://www.nature.com/articles/s41467-021-23174-0>Nature Communications volume 12, Article number: 2797
(2021)   
All-day fresh water harvesting by microstructured hydrogel
membranes  
Ye Shi, Ognjen Ilic, Harry A. Atwater & Julia R. Greer   
  
Abstract** -- Solar steam water purification and fog
collection are two independent processes that could enable
abundant fresh water generation. We developed a hydrogel
membrane that contains hierarchical three-dimensional
microstructures with high surface area that combines both
functions and serves as an all-day fresh water harvester. At
night, the hydrogel membrane efficiently captures fog droplets
and directionally transports them to a storage vessel. During
the daytime, it acts as an interfacial solar steam generator
and achieves a high evaporation rate of 3.64akgama2 ha1 under
1 sun enabled by improved thermal/vapor flow management. With
a homemade rooftop water harvesting system, this hydrogel
membrane can produce fresh water with a daily yield of
~34aLama2 in an outdoor test, which demonstrates its potential
for global water scarcity relief.  


---

 **<https://pubs.acs.org/doi/10.1021/acsami.7b17488>Fog Harvesting with Harps  
Weiwei Shi, et al.  
  
Abstract** -- Fog harvesting is a useful technique for
obtaining fresh water in arid climates. The wire meshes
currently utilized for fog harvesting suffer from dual
constraints: coarse meshes cannot efficiently capture
microscopic fog droplets, whereas fine meshes suffer from
clogging issues. Here, we design and fabricate fog harvesters
comprising an array of vertical wires, which we call afog
harpsa. Under controlled laboratory conditions, the
fog-harvesting rates for fog harps with three different wire
diameters were compared to conventional meshes of equivalent
dimensions. As expected for the mesh structures, the mid-sized
wires exhibited the largest fog collection rate, with a
drop-off in performance for the fine or coarse meshes. In
contrast, the fog-harvesting rate continually increased with
decreasing wire diameter for the fog harps due to efficient
droplet shedding that prevented clogging. This resulted in a
3-fold enhancement in the fog-harvesting rate for the harp
design compared to an equivalent mesh.  


---

  
**<https://news.mit.edu/2013/how-to-get-fresh-water-out-of-thin-air-0830>How to get fresh water out of thin air***Fog-harvesting system developed by MIT and Chilean
researchers could provide potable water for the worldas
driest regions.*...Fog-harvesting systems generally consist of a vertical
mesh, sort of like an oversized tennis net. Key to efficient
harvesting of the tiny airborne droplets of fog are three
basic parameters, the researchers found: the size of the
filaments in those nets, the size of the holes between those
filaments, and the coating applied to the filaments.  
  
Most existing systems turn out to be far from optimal, Park
says. Made of woven polyolefin mesh a a kind of plastic that
is easily available and inexpensive a they tend to have
filaments and holes that are much too large. As a result, they
may extract only about 2 percent of the water available in a
mild fog condition, whereas the new research shows that a
finer mesh could extract 10 percent or more, Park says.
Multiple nets deployed one behind another could then extract
even more, if so desired...  
The researchers found that controlling the size and structure
of the mesh and the physical and chemical composition of this
coating was essential to increasing the fog-collecting
efficiency. Detailed calculations and laboratory tests
indicate that the best performance comes from a mesh made of
stainless-steel filaments about three or four times the
thickness of a human hair, and with a spacing of about twice
that between fibers. In addition, the mesh is dip-coated,
using a solution that decreases a characteristic called
contact-angle hysteresis. This allows small droplets to more
easily slide down into the collecting gutter as soon as they
form, before the wind blows them off the surface and back into
the fog stream...  
...with the MIT-designed system, Park points out, 10 percent
of the fog moisture in the air passing through the new fog
collector system can potentially be captured...  
 **Langmuir, Vol 29/Issue 43, July 29, 2013  
Optimal Design of Permeable Fiber Network Structures for Fog
Harvesting  
Kyoo-Chul Park, et al.****Abstract** -- Fog represents a large untapped source
of potable water, especially in arid climates. Numerous plants
and animals use textural and chemical features on their
surfaces to harvest this precious resource. In this work, we
investigate the influence of the surface wettability
characteristics, length scale, and weave density on the
fog-harvesting capability of woven meshes. We develop a
combined hydrodynamic and surface wettability model to predict
the overall fog-collection efficiency of the meshes and cast
the findings in the form of a design chart. Two limiting
surface wettability constraints govern the re-entrainment of
collected droplets and clogging of mesh openings. Appropriate
tuning of the wetting characteristics of the surfaces,
reducing the wire radii, and optimizing the wire spacing all
lead to more efficient fog collection. We use a family of
coated meshes with a directed stream of fog droplets to
simulate a natural foggy environment and demonstrate a
five-fold enhancement in the fog-collecting efficiency of a
conventional polyolefin mesh. The design rules developed in
this work can be applied to select a mesh surface with optimal
topography and wetting characteristics to harvest enhanced
water fluxes over a wide range of natural convected fog
environments.  
 **[WO2023230244](1Patents/WO2023230244A1.pdf)
-- METHOD AND SYSTEM FOR FOG HARVESTING AND MIST ELIMINATION**


---

  
[**https://www.academia.edu/86497437/Self\_Sufficient\_Atmospheric\_Water\_Generator\_using\_Renewable\_Energy?email\_work\_card=view-paper**](https://www.academia.edu/86497437/Self_Sufficient_Atmospheric_Water_Generator_using_Renewable_Energy?email_work_card=view-paper)**Self Sufficient Atmospheric Water Generator using
Renewable Energy****By IRJET Journal  
[ [PDF](1Articles/Self_Sufficient_Atmospheric_Water_Genera.pdf) ]****Abstract --** There is a saying, "water has only two
aspects; when mixed with anything it's NEED, and when not it's
LIFE". This paper sets forth a solution to assist the struggle
against the scarcity of freshwater. Atmospheric Water
Generators (AWG) are a promising technology solution to the
water scarcity in the world. This paper takes into account
that the AWG fulfills certain prerequisites of portability,
simplicity, flexibility, maximize efficiency & minimize
cost.  
  


---

  
[**https://www.academia.edu/23216101/A\_Project\_on\_Atmospheric\_Water\_Generator\_with\_the\_Concept\_of\_Peltier\_Effect?email\_work\_card=title****International Journal of Advanced Computer Research,
A Project on Atmospheric Water Generator with the Concept
of Peltier Effect**](https://www.academia.edu/23216101/A_Project_on_Atmospheric_Water_Generator_with_the_Concept_of_Peltier_Effect?email_work_card=titleInternational









            Journal of Advanced Computer Research, A Project on
            Atmospheric Water Generator with the Concept of Peltier
            Effect)**Project on Atmospheric Water Generator with the Concept
of Peltier Effect****Vignesh Kumar, et al.****[ [PDF](1Articles/Project_on_Atmospheric_Water_Generator.pdf) ]****Abstract --** In many countries like India it is
difficult to obtain water resources for irrigation or other
purposes, especially in the arid regions. The problem of water
scarcity is also observed in other places of the world due to
lack of rainfall. However, in highly humid areas such as
places close to the sea, water can be obtained by condensing
the water vapour present in air. Here, the paper presents the
method to develop a water condensation system based on
thermoelectric cooler. The system consists of cooling
elements, heat exchange unit and air circulation unit. A solar
cell panel unit with a relevant high current output drives the
cooling elements through a controlling circuit. Atmospheric
Water Generator is a device that can convert atmospheric
moisture directly into usable and even drinkable water. It is
such a device which uses the principle of latent heat to
convert molecules of water vapour into water droplets. It has
been introduced a bit before, though it is not very common in
India and some other countries. It has a great application
standing on such age of technology where we all are running
behind renewable sources. This paper also describes the
experimental results and the systemas performance.  
  


---

  
[**https://www.sciencedirect.com/science/article/pii/S2542435121001781**](https://www.sciencedirect.com/science/article/pii/S2542435121001781)**Joule, Volume 5, Issue 7, 2021, pp. 1678-1703****Adsorption-based atmospheric water harvesting****M. Ejeian, R.Z. Wang** **[ [PDF](1Articles/EjeianAdsorbtionAWH.pdf) ]****Abstract --** In recent years, humidity has been
introduced as a reliable source of water. Among the various
technologies, adsorption-based atmospheric water harvesting
(ABAWH) has shown apparent advantages, especially in arid
areas. So far, most research in this field has been done on
developing modern and efficient adsorbents. The difference in
climatic conditions and applications makes it impossible to
introduce an ideal adsorbent. While adsorption kinetics is
preferred in quasi-continuous systems, adsorption capacity is
more desired in discontinuous systems. Despite its crucial
role, the adsorbent is only part of the process of converting
moisture to liquid water in an ABAWH system. Multicycle
systems, face challenges such as switching methods, sensible
heat, and RH fluctuations. Additionally, in solar-powered
systems, an auxiliary energy supply is necessary to continue
the production process at night. Moreover, the desorption rate
is limited by the distillation rate in the condenser. Using
hybrid surfaces and supply cold sources can improve system
performance. In this article, we have tried to consider the
whole ABAWH system where structures, strategies, and
components of a device in various applications, including
drinking water, agriculture, and water recovery, have been
examined, and the features, challenges, and path ahead of each
have been described with examples and practical ideas. This
article can guide designing and optimizing ABAWH devices
toward widespread use of this technology.  
  


---

  
**<https://www.sciencedirect.com/science/article/abs/pii/S0169809516302216>  
Atmospheric Research, Volume 182, 2016, pp. 156-162  
Assessment of atmospheric moisture harvesting by direct
cooling  
Ben Gido, a|, David M. Broday  
  
Abstract** -- The enormous amount of water vapor present
in the atmosphere may serve as a potential water resource. An
index is proposed for assessing the feasibility and energy
requirements of atmospheric moisture harvesting by a direct
cooling process. A climate-based analysis of different
locations reveals the global potential of this process. We
demonstrate that the Moisture Harvesting Index (MHI) can be
used for assessing the energy requirements of atmospheric
moisture harvesting. The efficiency of atmospheric moisture
harvesting is highly weather and climate dependent, with the
smallest estimated energy requirement found at the tropical
regions of the Philippines (0.23 kW/L). Less favorable
locations have much higher energy demands for the operation of
an atmospheric moisture harvesting device. In such locations,
using the MHI to select the optimal operation time periods
(during the day and the year) can reduce the specific energy
requirements of the process dramatically. Still, using current
technology the energy requirement of atmospheric moisture
harvesting by a direct air cooling process is significantly
higher than of desalination by reverse osmosis.  


---

  
[**https://www.sciencedirect.com/science/article/abs/pii/S0735193322000094**](https://www.sciencedirect.com/science/article/abs/pii/S0735193322000094)**International Communications in Heat and Mass
Transfer, Volume 132, 2022, Article 105887****Water production enhancement from the air moisture
using nanofluids-experimental investigation and
exergo-enviroeconomic analysis****Masoud Kaveh, a|, Abdollah Khalesi Doust****Abstract** -- Nowadays, the expansion of communities
and population growth has further highlighted the need for
clean water. To solve this problem, various methods have been
proposed. Water extraction from the air moisture is of these
methods which involve cooling the air to its dew point in
which the moisture transforms from the gas to the liquid
phase. In the present study, a device consisting of a
refrigeration cycle and a moisture distillation cycle was
designed to provide pure water from the air moisture.
Additionally, it was tried to enhance the system performance
by dispersing nanoparticles such as Cu and Al2O3 into the
working fluid of the heat exchanger. In this study, the
influence of various parameters (including inlet air velocity
and ambient humidity) on the performance of the system was
investigated. Finally, an exergo-enviroeconomic analysis was
performed in terms of water production and cost. Based on the
results, with increasing the air humidity from 40% to 60%, the
amount of water production of the system raised from 0.5 to
1.8 cc/min. It was also observed that dispersion of Cu and
Al2O3 nanoparticles enhanced the water production by around
43% and 29%, respectively. Moreover, an increment in inlet air
velocity reduced the water production; while increasing the
air humidity had a constructive effect on the system
performance. The economic analysis indicated that the water
production during a year increased by about 42% upon using Cu
nanofluid as the working fluid of the distillation cycle which
declined the water production cost by 32%.  
  


---

  
[**https://scholar.google.ch/citations?view\_op=view\_citation&hl=en&user=2SLbtkUAAAAJ&citation\_for\_view=2SLbtkUAAAAJ:8k81kl-MbHgC**](https://scholar.google.ch/citations?view_op=view_citation&hl=en&user=2SLbtkUAAAAJ&citation_for_view=2SLbtkUAAAAJ:8k81kl-MbHgC)****Angewandte Chemie,
Volume 134, Issue 13, e202200271**Polyzwitterionic hydrogels for efficient
atmospheric water harvesting**  

**Chuxin Lei, Youhong Guo, Weixin Guan, Hengyi
Lu, Wen Shi, Guihua Yu**

**Abstract --** Atmospheric water harvesting
(AWH) is regarded as one of the promising strategies for
freshwater production desirable to provide sustainable
water for landlocked and arid regions. Hygroscopic
materials have attracted widespread attention because of
their water harvesting performance. However, the
introduction of many inorganic salts often leads to
aggregation and leakage issues in practical use. Here,
polyzwitterionic hydrogels are developed as an effective
AWH material platform. Via antiapolyelectrolyte effects,
the hygroscopic salt coordinated with polymer chains could
capture moisture and enhance the swelling property,
leading to a strong moisture sorption capacity. The
hydrogel shows superior AWH performance (0.62agaga1,
120aminutes for equilibrium at 30a% relative humidity) and
produces 5.87aLakga1 freshwater per day. It is
anticipated that the polyzwitterionic hydrogels with
unique salt a|

  


---

  
[**https://scholar.google.ch/citations?view\_op=view\_citation&hl=en&user=2SLbtkUAAAAJ&citation\_for\_view=2SLbtkUAAAAJ:2osOgNQ5qMEC**](https://scholar.google.ch/citations?view_op=view_citation&hl=en&user=2SLbtkUAAAAJ&citation_for_view=2SLbtkUAAAAJ:2osOgNQ5qMEC)  
**Advanced Materials, Volume 34, Issue
12, Pages 2110079****Materials engineering for atmospheric water
harvesting: progress and perspectives****Hengyi Lu, Wen Shi, Youhong Guo. Weixin Guan, Chuxin
Lei, Guihua Yu** **Abstract --** Atmospheric water harvesting (AWH) is
emerging as a promising strategy to produce fresh water from
abundant airborne moisture to overcome the global clean water
shortage. The ubiquitous moisture resources allow AWH to be
free from geographical restrictions and potentially realize
decentralized applications, making it a vital parallel or
supplementary freshwater production approach to liquid water
resource?based technologies. Recent advances in regulating
chemical properties and micro/nanostructures of
moisture?harvesting materials have demonstrated new
possibilities to promote enhanced device performance and new
understandings. This perspective aims to provide a timely
overview on the state?of?the?art materials design and how they
serve as the active components in AWH. First, the key
processes of AWH, including vapor condensation, droplet
nucleation, growth, and departure are outlined, and a|  
  


---

  
[**https://scholar.google.ch/citations?view\_op=view\_citation&hl=en&user=2SLbtkUAAAAJ&citation\_for\_view=2SLbtkUAAAAJ:3fE2CSJIrl8C**](https://scholar.google.ch/citations?view_op=view_citation&hl=en&user=2SLbtkUAAAAJ&citation_for_view=2SLbtkUAAAAJ:3fE2CSJIrl8C)  
**Scalable super hygroscopic polymer films for sustainable
moisture harvesting in arid environments****Youhong Guo, Weixin Guan, Chuxin Lei, Hengyi Lu, Wen
Shi, Guihua Yu**  
**Abstract** --
Extracting ubiquitous atmospheric water is a sustainable
strategy to enable decentralized access to safely managed
water but remains challenging due to its limited daily water
output at low relative humidity (?30% RH). Here, we report
super hygroscopic polymer films (SHPFs) composed of renewable
biomasses and hygroscopic salt, exhibiting high water uptake
of 0.64a0.96?g?g?1 at 15a30% RH. Konjac glucomannan
facilitates the highly porous structures with enlarged
air-polymer interfaces for active moisture capture and water
vapor transport. Thermoresponsive hydroxypropyl cellulose
enables phase transition at a low temperature to assist the
release of collected water via hydrophobic interactions. With
rapid sorption-desorption kinetics, SHPFs operate 14a24 cycles
per day in arid environments, equivalent to a water yield of
5.8a13.3?L?kg?1. Synthesized via a simple casting method using
sustainable a|  
  


---

  
[**https://scholar.google.ch/citations?view\_op=view\_citation&hl=en&user=2SLbtkUAAAAJ&citation\_for\_view=2SLbtkUAAAAJ:8k81kl-MbHgC**](https://scholar.google.ch/citations?view_op=view_citation&hl=en&user=2SLbtkUAAAAJ&citation_for_view=2SLbtkUAAAAJ:8k81kl-MbHgC)****Angewandte Chemie,
Volume 134, Issue 13, e202200271**Polyzwitterionic hydrogels for efficient
atmospheric water harvesting**  

**Chuxin Lei, Youhong Guo, Weixin Guan, Hengyi
Lu, Wen Shi, Guihua Yu**

**Abstract --** Atmospheric water harvesting
(AWH) is regarded as one of the promising strategies for
freshwater production desirable to provide sustainable
water for landlocked and arid regions. Hygroscopic
materials have attracted widespread attention because of
their water harvesting performance. However, the
introduction of many inorganic salts often leads to
aggregation and leakage issues in practical use. Here,
polyzwitterionic hydrogels are developed as an effective
AWH material platform. Via antiapolyelectrolyte effects,
the hygroscopic salt coordinated with polymer chains could
capture moisture and enhance the swelling property,
leading to a strong moisture sorption capacity. The
hydrogel shows superior AWH performance (0.62agaga1,
120aminutes for equilibrium at 30a% relative humidity) and
produces 5.87aLakga1 freshwater per day. It is
anticipated that the polyzwitterionic hydrogels with
unique salt a|

  


---

[**https://interestingengineering.com/innovation/nanomaterial-pulls-water-from-air**](https://interestingengineering.com/innovation/nanomaterial-pulls-water-from-air)**New physics-defying nanomaterial gathers water
from air directly**The material works through capillary condensation, a
phenomenon where water vapor turns into liquid within
microscopic pores, even when the humidity is relatively low.  
  
...The researchers at the University of Pennsylvania School of
Engineering and Applied Science were reportedly testing a mix
of hydrophilic nanopores and hydrophobic polymers when they
unexpectedly noticed water droplets forming on the materialas
surface.  
  
aWe werenat even trying to collect water,a Daeyeon Lee, a
Russell Pearce and Elizabeth Cr Simian Heuer professor in
chemical and biomolecular engineering (CBE), said. aIt didnat
make sense. Thatas when we started asking questions.a  
  
**A passive water-harvesting platform**  
Upon analyzing the results, the team realized they had created
a material with the perfect balance of water-attracting
nanoparticles and water-repelling polyethylene, giving rise to
its unusual behavior.  
  


---

  
[**https://www.science.org/doi/10.1126/sciadv.adu8349**](https://www.science.org/doi/10.1126/sciadv.adu8349)**Amphiphilic nanopores that condense undersaturated
water vapor and exude water droplets****Baekmin Q. Kim, et al****Abstract --** Condensation of water vapor in
confined geometries, known as capillary condensation, is a
fundamental phenomenon with far-reaching implications. While
hydrophilic pores enable liquid formation from undersaturated
vapor without energy input, the condensate typically remains
confined, limiting practical utility. Here, we explore the use
of amphiphilic nanoporous polymer-infiltrated nanoparticle
films that condense and release liquid water under isothermal
and undersaturated conditions. By tuning the polymer fraction
and nanoparticle size, we optimize condensation and droplet
formation. As vapor pressure increases, voids fill with
condensate, which subsequently exudes onto the surface as
microscopic droplets. This behavior, enabled by a balance of
polymer hydrophobicity and capillarity, reveals how
amphiphilic nanostructures can drive accessible water
collection. Our findings provide design insights for materials
supporting energy-efficient water harvesting and heat
management without external input.  
  


---

**a  
<https://www.researchgate.net/publication/325847937>  
International Conference on Contemporary Affairs in
Architecture and Urbanism (ICCAUA-2018) Architectural Facade
Design Proposal for Water Production via Air Content  
DoAuA BodamyalA+/-zade, Halil Zafer Alibaba****[ [PDF](1Articles/ICCAUAirWells.pdf) ]**  
  
**Abstract --**
The main aim of this article is to analyse current facade
techniques, water producing systems and possible profits from
the application of adequate facade designs which could produce
water with the consideration of the needs of inhabitants.
Nowadays for certain countries lacking the financial power to
provide adequate water resources, the need of water harvesting
becomes more crucial. The proposed water harvesting systems
aim to increase the water resources by the application on the
buildingas facade. On the other hand, existing double skin
facades have only been used for shading, ventilation or
decorative purposes. This investigation focuses specifically
on the design of the facade in terms of the production of
water. The case study has taken place in North Cyprus,
Nicosia. A selected area will be evaluated and the need of the
water will be calculated then the proposal of the new facade
model will be introduced. Most importantly this proposed
facade model will meet the needs of water consumption of the
inhabitants. It produces 420 litre water per day by using
solar energy. With this system the application uses the sun
energy to extract water from the air, also the application has
potential to use as multi-functional purposes since it
collects water via humidity with turbine systems, it collects
up to 396 litres at temperatures between 86 degrees to 104
degrees (30 to 40 degrees Celsius) and between 80% and 90%
relative humidity.  
  


---

  
[**https://pmc.ncbi.nlm.nih.gov/articles/PMC10073925/**](https://pmc.ncbi.nlm.nih.gov/articles/PMC10073925/)**An overview of atmospheric water harvesting methods,
the inevitable path of the future in water supply****Zahra Ahrestani, et al.****[ [PDF](1Articles/AhrestaniOverviewAWHRA-013-D2RA07733G.pdf)
]****Abstract** -- Although science has made great
strides in recent years, access to fresh water remains a major
challenge for humanity due to water shortage for two-thirds of
the world's population. Limited access to fresh water becomes
more difficult due to the lack of natural resources of water.
Many of these resources are also contaminated by human
activities. Many attempts have been made to harvest water from
the atmosphere, and condensation systems have received much
attention. One of the challenges in generation systems is the
high consumption energy of the cooling feed, despite the
generation of large amounts of water from the atmosphere. As
other airborne contaminants condense with water vapor, the
water after harvesting needs to be treated, which adds to
construction and maintenance costs. Also, the need for high
relative humidity in condensation systems has led scientists
to find ways of atmospheric water harvesting at low relative
humidity and use renewable energy sources. Sorption systems
can absorb atmospheric water without the need for an energy
supply and spontaneously. Desiccants such as silica gel and
zeolite, due to their high affinity for water, can absorb
water vapor in the air through physical or physicochemical
bonding, but all of these have slow adsorption kinetics.
Therefore, it takes a long time for the water harvesting cycle
or they are not able to absorb water at low relative humidity,
and others need a lot of energy for the water desorption
phase. MetalaOrganic Frameworks (MOF) are porous materials
that, due to their special structure, are considered the most
promising material for atmospheric water harvesting at low
relative humidity. MOF-303 has been identified as the most
efficient material to date and can harvest 0.7 liters of water
per kilogram of MOF-303 at 10% RH and 27 A degC. MOFs can harvest
atmospheric water even in desert areas using only solar
energy, and the water produced is drinkable and does not need
to be treated. In this review, systems and methods of
atmospheric water harvesting will be studied and compared and
then the mechanism of adsorption and desorption in sorption
systems will be discussed in detail.  
  


---

  
**<https://pubs.aip.org/aip/pof/article-abstract/36/12/127135/3324420/Air-moisture-harvesting-in-soil-for-indoor?redirectedFrom=fulltext>Physics of Fluids 36, 127135 (2024)  
Air moisture harvesting in soil for indoor agriculture: A
comparative study of moisture dynamics in shallow porous
beds Available to Purchase  
Ashish D. Chaudhari, Vijesh V. Joshi****Abstract --** Indoor farming can mitigate water
scarcity, declining crop yields, and excessive chemical use in
agriculture. However, it demands innovative solutions to reach
its full potential. This paper presents a novel indoor plant
cultivation technique that leverages atmospheric moisture.
Shallow soil bed cooling from below can induce condensation
within the soil pores, providing a sustainable water source
for plant growth. We tested this method on wheat seed
cultivation, observing a 40% growth increase in seedlings with
cooled soil beds. We conducted a detailed study of moisture
dynamics in porous sand beds to understand the underlying
mechanisms of this technique. Choosing sand as a medium
isolated the effects of porosity, temperature, and capillary
action on moisture condensation. Sand's inertness allows a
concentrated analysis of moisture dynamics without
interference from chemical reactions or microbial activity.
Experiments with cooled sand of varying particle sizes showed
moisture condensation levels of 0.025, 0.042, and 0.092akg/kg
for coarse, fine, and superfine sand over 11 days. In soil,
moisture reached 0.124akg/kg over 22 days, highlighting the
impact of porosity, temperature, and capillary forces. Our
findings reveal exponential moisture increase over time and a
linear relationship between bed water content and specific
heat. The method is practical and adaptable, especially for
remote locations and arid regions, as renewable energy sources
can power it. This approach could revolutionize indoor
agriculture, particularly in controlled environment systems.
Controlling soil temperature can optimize growth conditions,
increase yields, and minimize environmental impact. It offers
versatility and scalability for various crops and systems.  
  


---

**<http://islandsky.com>  
Skywater  
  
2018 XPRIZE GRAND PRIZE WINNER IN WATER ABUNDANCE!  
  
Skywater Advanced Air-to-Water Technology**  
The most abundant source of fresh water is the Earthas
atmosphere. When atmospheric humidity condenses, it falls as
rain. Skywater replicates this natural process of condensation
by simulating the dew point, which allows it to make water
continuously, even in low humidity conditions. This is
Skywater's patented adiabatic distillation process.  
  
Again replicating nature's process, Skywater generates ozone
to purify the water. Ozone (O3), a natural occurring gas that
is produced in nature when it rains, binds with water to
eliminate bacteria and other impurities. Skywater does this by
pumping ozone through the water as it is collected. Unlike
other water treatment methods such as chlorine, ozone leaves
no taste.  
 **Skywater 250/75**The Worlds finest Atmospheric Water Generator that makes
clean, pure, fresh and healthy water. Produces up to 250
Liters of Water a day  


---

**<https://www.sciencedirect.com/science/article/abs/pii/S0169809516302216>****Atmospheric Research, Volume 182, 2016, pp. 156-162****Assessment of atmospheric moisture harvesting by direct
cooling****Ben Gido,  David M. Broday  
  
Abstract --** The enormous amount of water vapor present
in the atmosphere may serve as a potential water resource. An
index is proposed for assessing the feasibility and energy
requirements of atmospheric moisture harvesting by a direct
cooling process. A climate-based analysis of different
locations reveals the global potential of this process. We
demonstrate that the Moisture Harvesting Index (MHI) can be
used for assessing the energy requirements of atmospheric
moisture harvesting. The efficiency of atmospheric moisture
harvesting is highly weather and climate dependent, with the
smallest estimated energy requirement found at the tropical
regions of the Philippines (0.23 kW/L). Less favorable
locations have much higher energy demands for the operation of
an atmospheric moisture harvesting device. In such locations,
using the MHI to select the optimal operation time periods
(during the day and the year) can reduce the specific energy
requirements of the process dramatically. Still, using current
technology the energy requirement of atmospheric moisture
harvesting by a direct air cooling process is significantly
higher than of desalination by reverse osmosis.


---

**<https://www.sciencedirect.com/science/article/abs/pii/S0735193322000094>****International Communications in Heat and Mass Transfer,
Volume 132, 2022, Article 105887****Water production enhancement from the air moisture
using nanofluids -- experimental investigation and
exergo-enviroeconomic analysis****Masoud Kaveh, Abdollah Khalesi Doust**


---

**<https://pubmed.ncbi.nlm.nih.gov/30462515/>  
Langmuir, 2018 Dec 18;34(50):15259-15267.  
Efficient Fog Harvesting Based on 1D Copper Wire Inspired by
the Plant Pitaya  
Lieshuang Zhong, et al.  
  
Abstract** -- The leaf of the plant pitaya shows
excellent fog harvesting behavior through its 1D thorns with
wire-like microstructures. The thorns of it cannot provide
enough driving force for the droplet transportation by the
special structure and chemistry gradient as the cactus thorns,
but it showed efficient water supply which improved the fog
harvesting greatly. The mechanism is studied based on 1D
copper wire with similar 1D wire-like microstructure and
wettability. This structure can significantly reduce the
deviation of the fog-laden winds, and the surface intrinsic
hydrophility makes water accumulate on it in the form of
droplets, which endow it with an efficient water supply that
is a1/4100 times faster than that on a 2D-flat surface. In
addition, it can also enhance the fog capture and water
removal. The 3D fog collector composed of 1D microcopper wires
has been fabricated which show a high fog harvesting
efficiency of a1/413%. This work explains the role of 1D
wire-like microstructure in efficient fog harvesting in a
different view and provides new insight into the application
of developing a more efficient fog collector. **[CN115075338](1Patents/CN115075338A.pdf) --
Manufacturing and using method of in-fog water collection
power generation device**


---

[**https://pubmed.ncbi.nlm.nih.gov/21381707/**](https://pubmed.ncbi.nlm.nih.gov/21381707/)**Langmuir, 2011 Apr 5;27(7):3798-802.****Three-dimensional hierarchical structures for fog
harvesting****H G Andrews, et al.**  
**Abstract** -- Conventional fog-harvesting mechanisms are
effectively pseudo-2D surface phenomena in terms of water
droplet-plant interactions. In the case of the Cotula fallax
plant, a unique hierarchical 3D arrangement formed by its
leaves and the fine hairs covering them has been found to
underpin the collection and retention of water droplets on the
foliage for extended periods of time. The mechanisms of water
capture and release as a function of the surface 3D structure
and chemistry have been identified. Of particular note is that
water is retained throughout the entirety of the plant and
held within the foliage itself (rather than in localized
regions). Individual plant hairs form matlike structures
capable of supporting water droplets; these hairs wrap around
water droplets in a 3D fashion to secure them via a fine
nanoscale groove structure that prevents them from easily
falling to the ground.  
  


---

  
[**https://www.aquatechtrade.com/news/circular-economy/water-generation-atmosperic-air-tech-dive?gad\_source=5&gad\_campaignid=22788767674&gclid=EAIaIQobChMInsem8MuikAMV9GpHAR3f3xNEEAAYASAAEgI-E\_D\_BwE**](https://www.aquatechtrade.com/news/circular-economy/water-generation-atmosperic-air-tech-dive?gad_source=5&gad_campaignid=22788767674&gclid=EAIaIQobChMInsem8MuikAMV9GpHAR3f3xNEEAAYASAAEgI-E_D_BwE)**TECH DIVE: Atmospheric Water Generation**  
  


---

  
[**https://www.aqualonis.com/**](https://www.aqualonis.com/)**Aqualonis**Floating springs -- Harvesting drinking water with fog
nets. Each FogCollector is quick and easy to install while
requiring no maintenance. The collectors are carbon-neutral as
they are operated without energy. All materials are food-safe.
FogCollectors produce high-quality drinking water (approved by
WHO standards) and can provide water for agriculture and
forestry.  
  
[**https://www.aqualonis.com/\_files/ugd/dd8c81\_7dbd962863064dd9819699ac81ce946d.pdf**](https://www.aqualonis.com/_files/ugd/dd8c81_7dbd962863064dd9819699ac81ce946d.pdf)**Aqualonis Price list 2024**[**https://www.wipo.int/en/web/wipo-magazine/articles/harvesting-fog-to-relieve-water-shortages-in-arid-regions-62982**](https://www.wipo.int/en/web/wipo-magazine/articles/harvesting-fog-to-relieve-water-shortages-in-arid-regions-62982)**Harvesting fog to relieve water shortages in arid
regions**


---

  

**Videos**

  
[**https://www.youtube.com/watch?v=LtKXkCfWmyY**](https://www.youtube.com/watch?v=LtKXkCfWmyY)**Producing drinking water from fog: See how
Waterfoundations fog net CloudFisher works  // 
WasserStiftung**  
The CloudFisher collects drinking water from fog without
requiring energy. It is the first standard fog collector in
the world resisting to wind speeds of up to 120 km/h. It is
quickly installed, does not require additional energy and is
extremely low-maintenance. All used materials are food safe.  
The german Waterfoundation has spent two years researching and
developing the CloudFisher. It can supply hundreds of
thousands of people with top-quality drinking water complying
with the WHO drinking water standards. It is used around the
world in mountain or coastal regions with scarce rainfalls and
frequent fog.  
  
[**https://www.youtube.com/watch?v=0F7CQMd6mQ4**](https://www.youtube.com/watch?v=0F7CQMd6mQ4)**Worlds largest Fog-collector CloudFisher in Morocco a
Producing drinking water from fog  // 
WasserStiftung**The video shows the positive effects of the world's
largest fog collector system built by the WaterFoundation in
Morocco to supply the locals with clean water. The harvesting
of clouds and fog has become an increasingly important
technology in the worldwide search for new sources of drinking
water. For over ten years, the WaterFoundation has been
exploring the use of fog-collectors, supporting the work of
the Munich industrial designer Peter Trautwein\* in developing
an entirely new type of collector.  
The CloudFisher is the first production fog net capable of
withstanding wind speeds of up to 120 kph. It is quickly and
easily assembled, consumes no energy and requires very little
maintenance. All the materials used are food-safe. The highly
efficient CloudFisher system can supply people in many
countries with cheap and clean drinking water. The water
obtained in this way can also be used in farming and
stockbreeding, in reforestation projects or in industry.  
  
[**https://www.youtube.com/watch?v=5i6Se5oFoWA**](https://www.youtube.com/watch?v=5i6Se5oFoWA)**Turning vapor into drinking water - Catching fog in
response to drought   //  DW Documentary**  
The European Union is funding the "Life Nieblas" project to
find out more about the cloud catchersa potential. In the
north of Gran Canaria, researchers have managed to capture
tens of thousands of liters of water annually from passing
fogs and clouds. The water is being used to reforest a
burned-out region on the Canary Island.  
  
[**https://www.youtube.com/watch?v=YxRONAZoMDk****Desert Fog Nets Catch 10,000 Liters Of Water
Daily  //  Adam Danyal**](https://www.youtube.com/watch?v=YxRONAZoMDk Desert
            Fog Nets Catch 10,000 Liters Of Water Daily // Adam Danyal)  
These fog catchers in the Atacama Desert, Peru, also known as
the driest place on earth, capture 10,000 liters of freshwater
a day for drinking and growing sustainable food.   
  
[**https://www.youtube.com/watch?v=THJVuinPbc0**](https://www.youtube.com/watch?v=THJVuinPbc0)**Warka Water towers harvest drinkable water from the air
// Dezeen**  
Italian architect Arturo Vittori explains how his wooden Warka
Water structures can provide clean drinking water for rural
communities in the developing world.  
The tower consists of a bamboo frame supporting a mesh
polyester material inside. Rain, fog and dew condenses against
the mesh and trickles down a funnel into a reservoir at the
base of the structure. A fabric canopy shades the lower
sections of the tower to prevent the collected water from
evaporating.  
"Warka Water is currently represented by a tower that reaches
up to the sky to collect moisture from the air and brings it
down by gravity to the people," Vittori says.  
The performance of the towers varies depending on the weather,
but Vittori's aim is to create a structure that would enable
the community to extract up to 100 litres of water a day
without the reservoir running dry.  
  
[**https://www.youtube.com/watch?v=Mv6qZAtwKZM**](https://www.youtube.com/watch?v=Mv6qZAtwKZM)**Sahara AWH**[**https://www.youtube.com/**](https://www.youtube.com/)**These 5 innovations will change everything!****//  Leaf of Life**Since water harvesting is the solution to these problems,
we are going to highlight the top 5 water harvesting methods
that have been proven to work...  
  
[**https://www.youtube.com/watch?v=94SbtFgUv34**](https://www.youtube.com/watch?v=94SbtFgUv34)**Water from the air. Homemade atmospheric water
generator (AWG)****//** **Mr Yazdan**  
[**https://www.youtube.com/watch?v=21H-GOG9zlk**](https://www.youtube.com/watch?v=21H-GOG9zlk)**Functional Surfaces A4 - Fog Harvesting
(Advanced)**In the last part of this section we looked at the Namib
Desert Beetle. In this video we go further and study the
Cotula Fallax plant species which has a 3-dimensional water
capture mechanism. We also look at the issues faced by current
fog harvesting nets and the next generation of biomimetic
designs.  
  
[**https://www.youtube.com/watch?v=iDc6oqz9DEs****From Thin Air [  FogQuest ]  //  Tony
Makepeace**](https://www.youtube.com/watch?v=iDc6oqz9DEsFrom Thin
            Air [ FogQuest ] // Tony Makepeace)  
This short video introduces fog collection & FogQuest, a
Canadian non-profit organization dedicated to providing clean
water solutions in the developing world.  Shown in this
video are fog collection projects in Nepal, Guatemala and
Eritrea.  
  
[**https://www.youtube.com/watch?v=-6T3ICXWqjc**](https://www.youtube.com/watch?v=-6T3ICXWqjc) **This water harvester can turn desert air into
drinkable water  //  UC Berkeley** Last October, a University of California, Berkeley, team
headed down to the Arizona desert, plopped their newest
prototype water harvester into the backyard of a tract home
and started sucking water out of the air without any power
other than sunlight.  
The successful field test of their larger, next-generation
harvester proved what the team had predicted earlier in 2017:
that the water harvester can extract drinkable water every
day/night cycle at very low humidity and at low cost, making
it ideal for people living in arid, water-starved areas of the
world.  
  
[**https://www.youtube.com/watch?v=2GRgL4JEL0g**](https://www.youtube.com/watch?v=2GRgL4JEL0g)**How the aqualonis fog collector works**  
The video shows the process of collecting the smallest drops
of water from fog in specially developed three-dimensional
mesh. The aqualonis fog collector is the world's most
effective collector for obtaining drinking water from fog.  
  


---



---

**Atmospheric Humidity
Collector Patents**

  
[**https://worldwide.espacenet.com/advancedSearch?locale=en\_EP**](https://worldwide.espacenet.com/advancedSearch?locale=en_EP)  
  
 **[CA2478896](1Patents/CA2478896A1.pdf)
-- Combination Dehydrator & Condensed Water Dispenser**   
 **[CA497523](1Patents/CA497523A.pdf)
-- APPARATUS FOR EXTRACTING WATER FROM AIR**   
 **[CA774391](1Patents/CA774391A.pdf)
-- Method for Precipitating Atmospheric Water Masses**  
 **[CA2070098](1Patents/CA2070098A1.pdf)
-- APPARATUS FOR RECOVERING WATER FROM AIR...**  
 **[CH608260](1Patents/CH608260A5.pdf)
-- Process for Obtaining Service Water or Drinking Water...**  
   
****[CN1403192](1Patents/CN1403192A.pdf)
-- High-hydroscopicity adsorbent and its prepn**[CN2573556](1Patents/CN2573556Y.pdf) -- Solar adsorption device
for obtaining water**   
 **[CN101000289](1Patents/CN101000289A.pdf)
-- Fog collector and its application method**   
 **[CN101769831A](1Patents/CN101769831A.pdf)
--  Collecting device of fog and automatic-sorting
aerosol and application method thereof** **[CN10275488](1Patents/CN102175488A.pdf)
--  
[CN201326191Y](1Patents/CN201326191Y.pdf)
-- Fog-condensation water collector**   
 **[CN201993251](1Patents/CN201993251U.pdf)
--**  
 **[CN208349912U](1Patents/CN208349912U.pdf)
--**   
**[CN112916205](1Patents/CN112916205A.pdf) --
High-voltage electrostatic demisting system****[CN112916207](1Patents/CN112916207A.pdf) --
High-voltage electrostatic demisting control system, method
and device, and medium**   
****[CN115075338](1Patents/CN115075338A.pdf) --
Manufacturing and using method of in-fog water
collection power generation device****   
 **[DE3313711](1Patents/DE3313711A1.pdf)
-- Process and Apparatus for Obtaining Drinking Water**  
 **[DE19734887](1Patents/DE19734887A1.pdf)
-- Device for Obtaining Water from Air**   
  **[EP1952394](1Patents/EP1952394A2.pdf)-- SUPERHYDROPHILIC COATINGS**   
 **[EP1142835](1Patents/EP1142835A2.pdf)
-- Portable, Potable Water Recovery and Dispensing
Apparatus**   
 **[EP1629157](1Patents/EP1629157A1.pdf)
-- Device for the Extraction of Water from Atmospheric
Air**   
  **[ES1068289](1Patents/ES1068289U.pdf)
-- CAPTADOR TRIDIMENSIONAL DE AGUA DE NIEBLAS...**   
  **[FR2813087](1Patents/FR2813087A1.pdf)
-- Unit Recovering Atmospheric Moisture from Vapor or
Mist...**   
  **[G](1Patents/GB1164119A.pdf)******[B1164119](1Patents/GB1164119A.pdf) -- Device for Modifying
Atmospheric Conditions**[GB2453798](1Patents/GB2453798A.pdf) -- Water Extractor**   
 **[GB251689](1Patents/GB251689A.pdf)
-- Method of and Apparatus for Causing Precipitation of
Atmospheric Moisture...**  
 **[GB319778](1Patents/GB319778A.pdf)
-- Improved Means for Collecting Moisture from the
Atmosphere**   
 **[GB1200221](1Patents/GB1200221A.pdf)
-- PRODUCING FRESH WATER FROM AIR...********[GB1214720](1Patents/GB1214720A.pdf)
-- Fog Abatement & Cloud Modification**   
 [GB2064358](1Patents/GB2064358A.pdf)
-- EXTRACTING WATER FROM AIR**[GB2376401](1Patents/GB2376401A.pdf) -- Self-watering Plant
Pot**   
 **[GB2453798](1Patents/GB2453798A.pdf)
-- Water Extractor**   
   
  
 ****[JP2004057890](1Patents/JP2004057890A.pdf)
-- ULTRA WATER-REPELLENT SURFACE TYPE WATER EXTRACTION
DEVICE...**********[JP2004169321](1Patents/JP2004169321A.pdf)
-- METHOD FOR EXTRACTING WATER FROM AIR &
APPARATUS THEREFOR****[JP2004316183](1Patents/JP2004316183A.pdf)
-- Equipment & Method for Producing Fresh Water from
Atmospheric Moisture Content**   
   
 **[KR101369389](1Patents/KR101369389B1.pdf)
-- APPARATUS FOR PRODUCING WATER**   
 **[KR20010003009](1Patents/KR20010003009A.pdf)
-- EVAPORATOR OF DRAIN WATER FROM AIR CONDITIONER IN
ELEVATOR**   
 **[KR20000052036](1Patents/KR20000052036A.pdf)
-- EVAPORATOR FOR DISCHARGING WATER FROM AIR CONDITIONER OF
ELEVATOR**   
 **[KR20010077162](1Patents/KR20010077162A.pdf)
-- NON-POWERED APPARATUS AND METHOD FOR DRAINAGE OF
CONDENSATE WATER FROM AIR CONDITIONER**   
 **[KR20070028377](1Patents/KR20070028377A.pdf)
-- METHOD FOR EXTRACTING WATER FROM AIR, AND DEVICE
THEREFOR**   
 **[KR101492823](1Patents/KR101492823B1.pdf)
-- Water Harvester Having Micro-line Pattern**   
   
 **[MX2011010112](1Patents/MX2011010112A.pdf)
--   
  
[NL1030069](1Patents/NL1030069C1.pdf)
-- Atmospheric Water Collector...**   
   
 **[PT102351](1Patents/PT102351A.pdf)
--  Device for catching mist or fog microdrops or drops
of rain, and their combination for subsequent storage**   
   
**[RU2132602](1Patents/RU2132602C1.pdf)
-- Method for Accumulating Moisture in Full Fallows******[RU2143530](1Patents/RU2143530C1.pdf)
-- DEVICE FOR PRODUCING FRESH WATER FROM AIR******[RU2146744](1Patents/RU2146744C1.pdf)
-- Method for Producing Water from Air**   
****[RU2151973](1Patents/RU2151973C1.pdf)
-- PROCESS OF WINNING OF WATER FROM AIR****  **[RU2000393](1Patents/RU2000393C1.pdf) -- APPARATUS FOR EXTRACTION
OF WATER FROM AIR**   
****[RU2062838](1Patents/RU2062838C1.pdf)
-- DEVICE FOR TAKING DRINKING WATER FROM AIR****   
****[RU2064036](1Patents/RU2064036C1.pdf)
-- DEVICE FOR SEPARATING WATER FROM AIR********[RU2182562](1Patents/RU2182562C2.pdf)
-- Method of Producing Biologically Active Potable Water
with Reduced Content of Deuterium...****   
****[RU2185482](1Patents/RU2185482C2.pdf)
-- Apparatus for Receiving Biologically Pure Fresh
Water... out of Atmospheric Air**   
 [RU2190448](1Patents/RU2190448C2.pdf)
-- Independent Complex for Separating Moisture from
Air**   
 **[RU2235454](1Patents/RU2235454C1.pdf)
-- Method & Apparatus for Producing Acoustic Effect upon
Atmospheric Formations**   
**[RU2272877](1Patents/RU2272877C1.pdf)
-- Method for Obtaining Water from Air**   
 ******[RU2278790](1Patents/RU2278790C1.pdf) -- Method &
Apparatus for... Extraction of Water from
Atmosphere...**   
 [RU2278929](1Patents/RU2278790C1.pdf)
-- Vortex System for Condensing Moisture from
Atmospheric Air****   
 **[SU1751608](1Patents/SU1751608A1.pdf)
-- DEVICE FOR COLLECTING DRINKING WATER FROM AIR**  
   
 **[SG177029](1Patents/SG177029A1.pdf)
--  EXTENDED ATMOSPHERIC WATER HARVESTING MODULE**  
  **[UA66218](1Patents/UA66218A.pdf)
-- A PROCESS FOR PREPARATION OF SWEET WATER FROM AIR**  
   
 **[US1816592](1Patents/US1816592A.pdf)
-- Means to Recuperate the Atmospheric Moisture [ Knapen ]**   
 **[US2138689](1Patents/US2138689A.pdf)
-- Method for Gaining Water out of the Atmosphere**   
 **[US1816592](1Patents/US1816592A.pdf)
-- Means to Recuperate the Atmospheric Moisture** **[ Knapen ]**  
 **[US2138689](1Patents/US2138689A.pdf)
-- Method for Gaining Water out of the Atmosphere**   
 **[US2401560](1Patents/US2401560A.pdf)
-- Refrigerating apparatus**  
 **[US2462952](1Patents/US2462952A.pdf)
-- Solar Activated Dehumidifier**   
 **[US2761292](1Patents/US2761292A.pdf)
-- Device for obtaining fresh drinkable water**  
 **[US2779172](1Patents/US2779172A.pdf)
-- Thermo-electric dehumidifier**  
 **[US2919553](1Patents/US2919553A.pdf)
-- Combination fluid heater and dehumidifier**  
 **[US2944404](1Patents/US2944404A.pdf)
-- Thermoelectric dehumidifying apparatus**   
 **[US3400515](1Patents/US3400515A.pdf)
-- Production of water from the atmosphere**  
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-- Humidifier-dehumidifier device**  
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from moist air**  
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-- Process and System for Recovering Water from the
Atmosphere**  
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-- Charged Aerosol Generator with Uni-Electrode Source**  
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Air**  
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-- Underground heating and cooling system**  
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-- Solar Powered Dehumidifier Apparatus**  
**[US4255937](1Patents/US4255937A.pdf) -- Atmospheric water
collector**  
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-- Method and apparatus for the recovery of water from the
atmospheric air**  
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-- Water producing apparatus**  
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vegetation**   
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atmosphere**  
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-- Heat Energized Vapor Adsorbent Pump**  
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-- Ground moisture transfer system**  
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Bipolar Fog Abatement System**  
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-- Apparatus for continuously metering vapours contained in
the atmosphere**  
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Method and Device for Recovering in Liquid Form the Water
Present in the Atmosphere in Vapor Form** **[US5106512](1Patents/US5106512A.pdf)
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-- Potable water generator**   
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-- Potable air-water generator**   
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-- Atmospheric water extractor**   
****[US5259203](1Patents/US5259203A.pdf)
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from atmosphere**  
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Purification of Water from the Exhaust Gases of Internal
Combustion Engines**  
**[US5857344](1Patents/US5857344A.pdf)
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-- Method of Cloud Seeding**   
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-- Convection towers**   
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apparatus**   
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apparatus**   
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/ US6957543 -- Air Cycle Water Producing Machine**   
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]**   
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USING A DESICCANT**   
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Air**   
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Engines**   
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environment air**   
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human, animal and plants from hot and humid air**   
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[US7601206](1Patents/US7601206B2.pdf)
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conversion device**  **[US7954335](1Patents/US7954335B2.pdf)
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**[US8153233](1Patents/US8153233B2.pdf)
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[US8506675](1Patents/US8506675B2.pdf)
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method**   
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Water Collection Sheet and Method******[US8852320](1Patents/US8852320B2.pdf)
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silicate as a silica source**  **[US10954375](1Patents/US10954375B2.pdf)
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dessicant Vapor Separation System**  **[US12312777](1Patents/US12312777B2.pdf)
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from Hot Humid Air**   
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THEREFOR**   
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[US2008135495](1Patents/US2008135495A1.pdf)
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**[US2014190352](1Patents/US2014190352A1.pdf) --** **LIQUID
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CROSSLINKS**   
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SUPPLY PRODUCTION AND MANAGEMENT IN VEHICLES**   
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Mass...    
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CROSS-AXIS WIND TURBINE ENERGY CONVERTER  
[WO2007009184](1Patents/WO2007009184A1.pdf)
~ Gust Water Trap Apparatus**  **[WO2006017888](1Patents/WO2006017888A1.pdf)
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[WO2024105394](1Patents/WO2024105394A1.pdf)--  
ATMOSPHERIC WATER GENERATOR**


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